ECB deacylase mutants

ABSTRACT

A method for in vitro mutagenesis and recombination of polynucleotide sequences based on polymerase-catalyzed extension of primer oligonucleotides is disclosed. The method involves priming template polynucleotide(s) with random-sequences or defined-sequence primers to generate a pool of short DNA fragments with a low level of point mutations. The DNA fragments are subjected to denaturization followed by annealing and further enzyme-catalyzed DNA polymerization. This procedure is repeated a sufficient number of times to produce full-length genes which comprise mutants of the original template polynucleotides. These genes can be further amplified by the polymerase chain reaction and cloned into a vector for expression of the encoded proteins.

This application is a continuation of pending U.S. patent application Ser. No. 09/381,935, filed Sep. 27, 1999, which is a 371 of PCT/US98/05814, filed Mar. 25. 1998, which claims benefit of Ser. No. 60/041,666, filed Mar. 25, 1997; Ser. No. 60/045,211, filed Apr. 30, 1997, and Ser. No. 60/046,256, filed May 12, 1997.

The U.S. Government has certain rights in this invention pursuant to Grant No. DE-FG02-93-CH10578 awarded by the Department of Energy and Grant No. N00014-96-1-0340 awarded by the Office of Naval Research.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to in vitro methods for mutagenesis and recombination of polynucleotide sequences. More particularly, the present invention involves a simple and efficient method for in vitro mutagenesis and recombination of polynucleotide sequences based on polymerase-catalyzed extension of primer oligonucleotides, followed by gene assembly and optional gene amplification.

2. Description of Related Art

The publications and other reference materials referred to herein to describe the background of the invention and to provide additional detail regarding its practice are hereby incorporated by reference. For convenience, the reference materials are numerically referenced and grouped in the appended bibliography.

Proteins are engineered with the goal of improving their performance for practical applications. Desirable properties depend on the application of interest and may include tighter binding to a receptor, high catalytic activity, high stability, the ability to accept a wider (or narrower) range of substrates, or the ability to function in nonnatural environments such as organic solvents. A variety of approaches, including ‘rational’ design and random mutagenesis methods, have been successfully used to optimize protein functions (1). The choice of approach for a given optimization problem will depend upon the degree of understanding of the relationships between sequence, structure and function. The rational redesign of an enzyme catalytic site, for example, often requires extensive knowledge of the enzyme structure, the structures of its complexes with various ligands and analogs of reaction intermediates and details of the catalytic mechanism. Such information is available only for a very few well-studied systems; little is known about the vast majority of potentially interesting enzymes. Identifying the amino acids responsible for existing protein functions and those which might give rise to new functions remains an often-overwhelming challenge. This, together with the growing appreciation that many protein functions are not confined to a small number of amino acids, but are affected by residues far from active sites, has prompted a growing number of groups to turn to random mutagenesis, or ‘directed’ evolution, to engineer novel proteins (1).

Various optimization procedures such as genetic algorithms (2,3) and evolutionary strategies (4,5) have been inspired by natural evolution. These procedures employ mutation, which makes small random changes in members of the population, as well as crossover, which combines properties of different individuals, to achieve a specific optimization goal. There also exist strong interplays between mutation and crossover, as shown by computer simulations of different optimization problems (6-9). Developing efficient and practical experimental techniques to mimic these key processes is a scientific challenge. The application of such techniques should allow one, for example, to explore and optimize the functions of biological molecules such as proteins and nucleic acids, in vivo or even completely free from the constraints of a living system (10,11).

Directed evolution, inspired by natural evolution, involves the generation and selection or screening of a pool of mutated molecules which has sufficient diversity for a molecule encoding a protein with altered or enhanced function to be present therein. It generally begins with creation of a library of mutated genes. Gene products which show improvement with respect to the desired property or set of properties are identified by selection or screening. The gene(s) encoding those products can be subjected to further cycles of the process in order to accumulate beneficial mutations. This evolution can involve few or many generations, depending on how far one wishes to progress and the effects of mutations typically observed in each generation. Such approaches have been used to create novel functional nucleic acids (12), peptides and other small molecules (12), antibodies (12), as well as enzymes and other proteins (13,14,16). Directed evolution requires little specific knowledge about the product itself, only a means to evaluate the function to be optimized. These procedures are even fairly tolerant to inaccuracies and noise in the function evaluation (15).

The diversity of genes for directed evolution can be created by introducing new point mutations using a variety of methods, including mutagenic PCR (15) or combinatorial cassette mutagenesis (16). The ability to recombine genes, however, can add an important dimension to the evolutionary process, as evidenced by its key role in natural evolution. Homologous recombination is an important natural process in which organisms exchange genetic information between related genes, increasing the accessible genetic diversity within a species. While introducing potentially powerful adaptive and diversification competencies into their hosts, such pathways also operate at very low efficiencies, often eliciting insignificant changes in pathway structure or function, even after tens of generations. Thus, while such mechanisms prove beneficial to host organisms/species over geological time spans, in vivo recombination methods represent cumbersome, if not unusable, combinatorial processes for tailoring the performance of enzymes or other proteins not strongly linked to the organism's intermediary metabolism and survival.

Several groups have recognized the utility of gene recombination in directed evolution. Methods for in vivo recombination of genes are disclosed, for example, in published PCT application WO 97/07205 and U.S. Pat. No. 5,093,257. As discussed above, these in vivo methods are cumbersome and poorly optimized for rapid evolution of function. Stemmer has disclosed a method for in vitro recombination of related DNA sequences in which the parental sequences are cut into fragments, generally using an enzyme such as DNase I, and are reassembled (17,18,19). The non-random DNA fragmentation associated with DNase I and other endonucleases, however, introduces bias into the recombination and limits the recombination diversity. Furthermore, this method is limited to recombination of double-stranded polynucleotides and cannot be used on single-stranded templates. Further, this method does not work well with certain combinations of genes and primers. It is not efficient for recombination of short sequences (less than 200 nucleotides (nts)), for example. Finally, it is quite laborious, requiring several steps. Alternative, convenient methods for creating novel genes by point mutagenesis and recombination in vitro are needed.

SUMMARY OF THE INVENTION

The present invention provides a new and significantly improved approach to creating novel polynucleotide sequences by point mutation and recombination in vitro of a set of parental sequences (the templates). The novel polynucleotide sequences can be useful in themselves (for example, for DNA-based computing), or they can be expressed in recombinant organisms for directed evolution of the gene products. One embodiment of the invention involves priming the template gene(s) with random-sequence oligonucleotides to generate a pool of short DNA fragments. Under appropriate reaction conditions, these short DNA fragments can prime one another based on complementarity and thus can be reassembled to form full-length genes by repeated thermocycling in the presence of thermostable DNA polymerase. These reassembled genes, which contain point mutations as well as novel combinations of sequences from different parental genes, can be further amplified by conventional PCR and cloned into a proper vector for expression of the encoded proteins. Screening or selection of the gene products leads to new variants with improved or even novel functions. These variants can be used as they are, or they can serve as new starting points for further cycles of mutagenesis and recombination.

A second embodiment of the invention involves priming the template gene(s) with a set of primer oligonucleotides of defined sequence or defined sequence exhibiting limited randomness to generate a pool of short DNA fragments, which are then reassembled as described above into full length genes.

A third embodiment of the invention involves a novel process we term the ‘staggered extension’ process, or StEP. Instead of reassembling the pool of fragments created by the extended primers, full-length genes are assembled directly in the presence of the template(s). The StEP consists of repeated cycles of denaturation followed by extremely abbreviated annealing/extension steps. In each cycle the extended fragments can anneal to different templates based on complementarity and extend a little further to create “recombinant cassettes.” Due to this template switching, most of the polynucleotides contain sequences from different parental genes (i.e. are novel recombinants). This process is repeated until full-length genes form. It can be followed by an optional gene amplification step.

The different embodiments of the invention provide features and advantages for different applications. In the most preferred embodiment, one or more defined primers or defined primers exhibiting limited randomness which correspond to or flank the 5′ and 3′ ends of the template polynucleotides are used with StEP to generate gene fragments which grow into the novel full-length sequences. This simple method requires no knowledge of the template sequence(s).

In another preferred embodiment, multiple defined primers or defined primers exhibiting limited randomness are used to generate short gene fragments which are reassembled into full-length genes. Using multiple defined primers allows the user to bias in vitro recombination frequency. If sequence information is available, primers can be designed to generate overlapping recombination cassettes which increase the frequency of recombination at particular locations. Among other features, this method introduces the flexibility to take advantage of available structural and functional information as well as information accumulated through previous generations of mutagenesis and selection (or screening).

In addition to recombination, the different embodiments of the primer-based recombination process will generate point mutations. It is desirable to know and be able to control this point mutation rate, which can be done by manipulating the conditions of DNA synthesis and gene reassembly. Using the defined-primer approach, specific point mutations can also be directed to specific positions in the sequence through the use of mutagenic primers.

The various primer-based recombination methods in accordance with this invention have been shown to enhance the activity of Actinoplanes utahensis ECB deacylase over a broad range of pH values and in the presence of organic solvent and to improve the thermostability of Bacillus subtilis subtilisin E. DNA sequencing confirms the role of point mutation and recombination in the generation of novel sequences. These protocols have been found to be both simple and reliable.

The above discussed and many other features and attendant advantages will become better understood by reference to the following detailed description when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts recombination in accordance with the present invention using random-sequence primers and gene reassembly. The steps shown are: a) Synthesis of single-stranded DNA fragments using mesophilic or thermophilic polymerase with random-sequence oligonucleotides as primers (primers not shown); b) Removal of templates; c) Reassembly with thermophilic DNA polymerase; d) Amplification with thermostable polymerase(s); e) Cloning and Screening (optional); and f) Repeat the process with selected gene(s) (optional).

FIG. 2 depicts recombination in accordance with the present invention using defined primers. The method is illustrated for the recombination of two genes, where x=mutation. The steps diagrammed are: a) The genes are primed with defined primers in PCR reactions that can be done separately (2 primers per reaction) or combined (multiple primers per reaction); c) Initial products are formed until defined primers are exhausted. Template is removed (optional; d) Initial fragments prime and extend themselves in further cycles of PCR with no addition of external primers. Assembly continues until full-length genes are formed; e) (optional) Full-length genes are amplified in a PCR reaction with external primers; f) (optional) Repeat the process with selected gene(s).

FIG. 3 depicts recombination in accordance with the present invention using two defined flanking primers and StEP. Only one primer and two single strands from two templates are shown here to illustrate the recombination process. The outlined steps are: a) After denaturation, template genes are primed with one defined primer; b) Short fragments are produced by primer extension for a short time; c) In the next cycle of StEP, fragments are randomly primed to the templates and extended further; d) Denaturation and annealing/extension is repeated until full-length genes are made (visible on an agarose gel); e) Full-length genes are purified, or amplified in a PCR reaction with external primers (optional); f) (optional) Repeat the process with selected gene(s).

FIG. 4 is a diagrammatic representation of the results of the recombination of two genes using two flanking primers and staggered extension in accordance with the present invention. DNA sequences of five genes chosen from the recombined library are indicated, where x is a mutation present in the parental genes, and the triangle represents a new point mutation.

FIG. 5 is a diagrammatic representation of the sequences of the pNB esterase genes described in Example 3. Template genes 2-13 and 5-B12 were recombined using the defined primer approach. The positions of the primers are indicated by arrows, and the positions where the parental sequences differ from one another are indicated by x's. New point mutations are indicated by triangles. Mutations identified in these recombined genes are listed (only positions which differ in the parental sequences are listed). Both 6E6 and 6H1 are recombination products of the template genes.

FIG. 6 shows the positions and sequences of the four defined internal primers used to generate recombined genes from template genes R1 and R2 by interspersed primer-based recombination. Primer P50F contains a mutation (A→T at base position 598) which simultaneously eliminates a HindIII restriction site and adds a new unique NheI site. Gene R2 also contains a mutation A→G at the same base position, which eliminates the HindIII site.

FIG. 7 is an electrophoresis gel which shows the results of the restriction-digestion analysis of plasmids from the 40 clones.

FIG. 8 shows the results of sequencing ten genes from the defined primer-based recombination library. Lines represent 986-bp of subtilisin E gene including 45 nt of its prosequence, the entire mature sequence and 113 nt after the stop codon. Crosses indicate positions of mutations from parent gene R1 and R2, while triangles indicate positions of new point mutations introduced during the recombination procedure. Circles represent the mutation introduced by the mutagenic primer P50F.

FIG. 9 depicts the results of applying the random-sequence primer recombination method to the gene for Actinoplanes utahensis ECB deacylase. (a) The 2.4 kb ECB deacylase gene was purified from an agarose gel. (b) The size of the random priming products ranged from 100 to 500 bases. (c) Fragments shorter than 300 bases were isolated. (d) The purified fragments were used to reassemble the full-length gene with a smear background. (e) A single PCR product of the same size as the ECB deacylase gene was obtained after conventional PCR with the two primers located at the start and stop regions of this gene. (f) After digestion with Xho I and Psh AI, the PCR product was cloned into a modified pIJ702 vector to form a mutant library. (g) Introducing this library into Streptomyces lividans TK23 resulted in approximately 71% clones producing the active ECB deacylase.

FIG. 10 shows the specific activity of the wild-type ECB deacylase and mutant M16 obtained in accordance with the present invention.

FIG. 11 shows pH profiles of activity of the wild-type ECB deacylase and mutant M 16 obtained in accordance with the present invention.

FIG. 12 shows the DNA sequence analysis of 10 clones randomly chosen from the library/Klenow. Lines represent 986-bp of subtilisin E gene including 45 nt of its prosequence, the entire mature sequence and 113 nt after the stop codon. Crosses indicate positions of mutations from R1 and R2, while triangles indicate positions of new point mutations introduced during the random-priming recombination process. FIGS. 13a-13 e Thermostability index profiles of the screened clones from the five libraries produced using different polymerases: a) library/Klenow, b) library/T4, c) library/Sequenase, d) library/Stoffel and e) library/Pfu. Normalized residual activity (A_(r)/A_(i)) after incubation at 65° C. was used as an index of the enzyme thermostability. Data were sorted and plotted in descending order.

DETAILED DESCRIPTION OF THE INVENTION

In one preferred embodiment of the present invention, a set of primers with all possible nucleotide sequence combinations (dp(N)_(L) where L=primer length) is used for the primer-based recombination. It has been known for years that oligodeoxynucleotides of different lengths can serve as primers for initiation of DNA synthesis on single-stranded templates by the Klenow fragment of E.coli polymerase I (21). Although they are smaller than the size of a normal PCR primer (i.e. less than 13 bases), oligomers as short as hexanucleotides can adequately prime the reaction and are frequently used in labeling reactions (22). The use of random primers to create a pool of gene fragments followed by gene reassembly in accordance with the invention is shown in FIG. 1. The steps include generation of diverse “breeding blocks” from the single-stranded polynucleotide templates through random priming, reassembly of the full-length DNA from the generated short, nascent DNA fragments by thermocycling in the presence of DNA polymerase and nucleotides, and amplification of the desired genes from the reassembled products by conventional PCR for further cloning and screening. This procedure introduces new mutations mainly at the priming step but also during other steps. These new mutations and the mutations already present in the template sequences are recombined during reassembly to create a library of novel DNA sequences. The process can be repeated on the selected sequences, if desired.

To carry out the random priming procedure, the template(s) can be single- or denatured double-stranded polynucleotide(s) in linear or closed circular form. The templates can be mixed in equimolar amounts, or in amounts weighted, for example, by their functional attributes. Since, at least in some cases, the template genes are cloned in vectors into which no additional mutations should be introduced, they are usually first cleaved with restriction endonuclease(s) and purified from the vectors. The resulting linear DNA molecules are denatured by boiling, annealed to random-sequence oligodeoxynucleotides and incubated with DNA polymerase in the presence of an appropriate amount of dNTPs. Hexanucleotide primers are preferred, although longer random primers (up to 24 bases) may also be used, depending on the DNA polymerase and conditioning used during random priming synthesis. Thus the oligonucleotides prime the DNA of interest at various positions along the entire target region and are extended to generate short DNA fragments complementary to each strand of the template DNA. Due to events such as base mis-incorporations and mispriming, these short DNA fragments also contain point mutations. Under routinely established reaction conditions, the short DNA fragments can prime one another based on homology and be reassembled into full-length genes by repeated thermocycling in the presence of thermostable DNA polymerase. The resulting full-length genes will have diverse sequences, most of which, however, still resemble that of the original template DNA. These sequences can be further amplified by a conventional PCR and cloned into a vector for expression. Screening or selection of the expressed mutants should lead to variants with improved or even new specific functions. These variants can be immediately used as partial solutions to a practical problem, or they can serve as new starting points for further cycles of directed evolution.

Compared to other techniques used for protein optimization, such as combinatorial cassette and oligonucleotide-directed mutagenesis (24,25,26), error-prone PCR (27, 28), or DNA shuffling (17,18,19), some of the advantages of the random-primer based procedure for in vitro protein evolution are summarized as follows:

1. The template(s) used for random priming synthesis may be either single- or double-stranded polynucleotides. In contrast, error-prone PCR and the DNA shuffling method for recombination (17,18,19) necessarily employ only double-stranded polynucleotides. Using the technique described here, mutations and/or crossovers can be introduced at the DNA level by using different DNA-dependent DNA polymerases, or even directly from mRNA by using different RNA-dependent DNA polymerases. Recombination can be performed using single-stranded DNA templates.

2. In contrast to the DNA shuffling procedure, which requires fragmentation of the double-stranded DNA template (generally done with DNAse I) to generate random fragments, the technique described here employs random priming synthesis to obtain DNA fragments of controllable size as “breeding blocks” for further reassembly (FIG. 1). One immediate advantage is that two sources of nuclease activity (DNase I and 5′-3′ exonuclease) are eliminated, and this allows easier control over the size of the final reassembly and amplification gene fragments.

3. Since the random primers are a population of synthetic oligonucleotides that contain all four bases in every position, they are uniform in their length and lack a sequence bias. The sequence heterogeneity allows them to form hybrids with the template DNA strands at many positions, so that every nucleotide of the template (except, perhaps, those at the extreme 5′ terminus) should be copied at a similar frequency into products. In this way, both mutations and crossover may happen more randomly than, for example, with error-prone PCR or DNA shuffling.

4. The random-primed DNA synthesis is based on the hybridization of a mixture of hexanucleotides to the DNA templates, and the complementary strands are synthesized from the 3′-OH termini at the random hexanucleotide primer using polymerase and the four deoxynucleotide triphosphates. Thus the reaction is independent of the length of the DNA template. DNA fragments of 200 bases length can be primed equally well as linearized plasmid or λ DNA (29). This is particularly useful for engineering peptides, for example.

5. Since DNase I is an endonuclease that hydrolyzes double-stranded DNA preferentially at sites adjacent to pyrimidine nucleotides, its use in DNA shuffling may result in bias (particularly for genes with high G+C or high A+T content) at the step of template gene digestion. Effects of this potential bias on the overall mutation rate and recombination frequency may be avoided by using the random-priming approach. Bias in random priming due to preferential hybridization to GC-rich regions of the template DNA could be overcome by increasing the A and T content in the random oligonucleotide library.

An important part of practicing the present invention is controlling the average size of the nascent, single-strand DNA synthesized during the random priming process. This step has been studied in detail by others. Hodgson and Fisk (30) found that the average size of the synthesized single-strand DNA is an inverse function of primer concentration: length=k/{square root over (lnPc)}, where P_(c) is the primer concentration. The inverse relationship between primer concentration and output DNA fragment size may be due to steric hindrance. Based on this guideline, proper conditions for random-priming synthesis can be readily set for individual genes of different lengths.

Since dozens of polymerases are currently available, synthesis of the short, nascent DNA fragments can be achieved in a variety of fashions. For example, bacteriophage T4 DNA polymerase (23) or T7 sequenase version 2.0 DNA polymerase (31,32) can be used for the random priming synthesis.

For single-stranded polynucleotide templates (particularly for RNA templates), a reverse transcriptase is preferred for random-priming synthesis. Since this enzyme lacks 3′→5′ exonuclease activity, it is rather prone to error. In the presence of high concentrations of dNTPs and Mn²⁺, about 1 base in every 500 is misincorporated (29).

By modifying the reaction conditions, the PCR can be adjusted for the random priming synthesis using thermostable polymerase for the short, nascent DNA fragments. An important consideration is to identify by routine experimentation the reaction conditions which ensure that the short random primers can anneal to the templates and give sufficient DNA amplification at higher temperatures. We have found that random primers as short as dp(N)₁₂ can be used with PCR to generate the extended primers. Adapting the PCR to the random priming synthesis provides a convenient method to make short, nascent DNA fragments and makes this random priming recombination technique very robust.

In many evolution scenarios, recombination should be conducted between oligonucleotide sequences for which sequence information is available for at least some of the template sequences. In such scenarios, it is often possible to define and synthesize a series of primers which are interspersed between the various mutations. When defined primers are used, they can be between 6 and 100 bases long. In accordance with the present invention, it was discovered that by allowing these defined primers to initiate a series of overlapping primer extension reactions (which may be facilitated by thermocycling), it is possible to generate recombination cassettes each containing one or more of the accumulated mutations, allelic or isotypic differences between templates. Using the defined primers in such a way that overlapping extension products are generated in the DNA polymerization reactions, exhaustion of available primer leads to the progressive cross-hybridization of primer extended products until complete gene products are generated. The repeated rounds of annealing, extension and denaturation assure recombination of each overlapping cassette with every other.

A preferred embodiment of the present invention involves methods in which a set of defined oligonucleotide primers is used to prime DNA synthesis. FIG. 2 illustrates an exemplary version of the present invention in which defined primers are used. Careful design and positioning of oligonucleotide primers facilitates the generation of non-random extended recombination primers and is used to determine the major recombination (co-segregation) events along the length of homologous templates.

Another embodiment of the present invention is an alternative approach to primer-based gene assembly and recombination in the presence of template. Thus, as illustrated in FIG. 3, the present invention includes recombination in which enzyme-catalyzed DNA polymerization is allowed to proceed only briefly (by limiting the time and lowering the temperature of the extension step) prior to denaturation. Denaturation is followed by random annealing of the extended fragments to template sequences and continued partial extension. This process is repeated multiple times, depending on the concentration of primer and template, until full length sequences are made. This process is called staggered extension, or StEP. Although random primers can also be used for StEP, gene synthesis is not nearly as efficient as with defined primers. Thus defined primers are preferred.

In this method, a brief annealing/extension step(s) is used to generate the partially extended primer. A typical annealing/extension step is done under conditions which allow high fidelity primer annealing (T_(annealing) greater than T_(m) ⁻²⁵), but limit the polymerization/extension to no more than a few seconds (or an average extension to less than 300 nts). Minimum extensions are preferably on the order of 20-50 nts. It has been demonstrated that thermostable DNA polymerases typically exhibit maximal polymerization rates of 100-150 nucleotides/second/enzyme molecule at optimal temperatures, but follow approximate Arrhenius kinetics at temperatures approaching the optimum temperature (T_(opt)). Thus, at a temperature of 55° C., a thermostable polymerase exhibits only 20-25% of the steady state polymerization rate that it exhibits at 72° C. (T_(opt)), or 24 nts/second (40). At 37° C. and 22° C., Taq polymerase is reported to have extension activities of 1.5 and 0.25 nts/second, respectively (24). Both time and temperature can be routinely altered based on the desired recombination events and knowledge of basic polymerase kinetics and biochemistry.

The progress of the staggered extension process is monitored by removing aliquots from the reaction tube at various time points in the primer extension and separating DNA fragments by agarose gel electrophoresis. Evidence of effective primer extension is seen from the appearance of a low molecular weight ‘smear’ early in the process which increases in molecular weight with increasing cycle number.

Unlike the gene amplification process (which generates new DNA exponentially), STEP generates new DNA fragments in an additive manner in its early cycles which contain DNA segments corresponding to the different template genes. Under non-amplifying conditions, 20 cycles of StEP generates a maximal molar yield of DNA of approximately 40 times the initial template concentration. In comparison, the idealized polymerase chain reaction process for gene amplification is multiplicative throughout, giving a maximal molar yield of approximately 1×10⁶-fold through the same number of steps. In practice, the difference between the two processes can be observed by PCR, giving a clear ‘band’ after only a few (less than 10) cycles when starting with template at concentrations of less than 1 ng/ul and primers at 10-500-fold excess (vs. 10⁶-fold excess typical of gene amplification). Under similar reaction conditions, the StEP would be expected to give a less visible ‘smear’, which increases in molecular weight with increasing number of cycles. When significant numbers of primer extended DNA molecules begin to reach sizes of greater than ½ the length of the full length gene, a rapid jump in molecular weight occurs, as half-extended forward and reverse strands begin to cross-hybridize to generate fragments nearly 2 times the size of those encountered to that point in the process. At this point, consolidation of the smear into a discrete band of the appropriate molecular weight can occur rapidly by either continuing to subject the DNA to StEP, or altering the thermocycle to allow complete extension of the primed DNA to drive exponential gene amplification.

Following gene assembly (and, if necessary, conversion to double stranded form) recombined genes are amplified (optional), digested with suitable restriction enzymes and ligated into expression vectors for screening of the expressed gene products. The process can be repeated if desired, in order to accumulate sequence changes leading to the evolution of desired functions.

The staggered extension and homologous gene assembly process (StEP) represents a powerful, flexible method for recombining similar genes in a random or biased fashion. The process can be used to concentrate recombination within or away from specific regions of a known series of sequences by controlling placement of primers and the time allowed for annealing/extension steps. It can also be used to recombine specific cassettes of homologous genetic information generated separately or within a single reaction. The method is also applicable to recombining genes for which no sequence information is available but for which functional 5′ and 3′ amplification primers can be prepared. Unlike other recombination methods, the staggered extension process can be run in a single tube using conventional procedures without complex separation or purification steps.

Some of the advantages of the defined-primer embodiments of the present invention are summarized as follows:

1. The StEP method does not require separation of parent molecules from assembled products.

2. Defined primers can be used to bias the location of recombination events.

3. StEP allows the recombination frequency to be adjusted by varying extension times.

4. The recombination process can be carried out in a single tube.

5. The process can be carried out on single-stranded or double-stranded polynucleotides.

6. The process avoids the bias introduced by DNase I or other endonucleases.

7. Universal primers can be used.

8. Defined primers exhibiting limited randomness can be used to increase the frequency of mutation at selected areas of the gene.

As will be appreciated by those skilled in the art, several embodiments of the present invention are possible. Exemplary embodiments include:

1. Recombination and point mutation of related genes using only defined flanking primers and staggered extension.

2. Recombination and mutation of related genes using flanking primers and a series of internal primers at low enough concentration that exhaustion of the primers will occur over the course of the thermocycling, forcing the overlapping gene fragments to cross-hybridize and extend until recombined synthetic genes are formed.

3. Recombination and mutation of genes using random-sequence primers at high concentration to generate a pool of short DNA fragments which are reassembled to form new genes.

4. Recombination and mutation of genes using a set of defined primers to generate a pool of DNA fragments which are reassembled to form new genes.

5. Recombination and mutation of single-stranded polynucleotides using one or more defined primers and staggered extension to form new genes.

6. Recombination using defined primers with limited randomness at more than 30% or more than 60% of the nucleotide positions within the primer.

Examples of practice showing use of the primer-based recombination method are as follows.

EXAMPLE 1 Use of Defined Flanking Primers and Staggered Extension to Recombine and Enhance the Thermostability of Subtilisin E

This example shows how the defined primer recombination method can be used to enhance the thermostability of subtilisin E by recombination of two genes known to encode subtilisin E variants with thermostabilities exceeding that of wild-type subtilisin E. This example demonstrates the general method outlined in FIG. 3 utilizing only two primers corresponding to the 5′ and 3′ ends of the templates.

As outlined in FIG. 3, extended recombination primers are first generated by the staggered extension process (StEP), which consists of repeated cycles of denaturation followed by extremely abbreviated annealing/extension step(s). The extended fragments are reassembled into full-length genes by thermocycling-assisted homologous gene assembly in the presence of a DNA polymerase, followed by an optional gene amplification step.

Two thermostable subtilisin E mutants R1 and R2 were used to test the defined primer based recombination technique using staggered extension. The positions at which these two genes differ from one another are shown in Table 1. Among the ten nucleotide positions that differ in R1 and R2, only those mutations leading to amino acid substitutions Asn 181-Asp (N181D) and Asn 218-Ser (N218S) confer thermostability. The remaining mutations are neutral with respect to their effects on thermostability (33). The half-lives at 65° C. of the single variants N181D and N218S are approximately 3-fold and 2-fold greater than that of wild type subtilisin E, respectively, and their melting temperatures, T_(m), are 3.7° C. and 3.2° C. higher than that of wild type enzyme, respectively. Random recombination events that yield sequences containing both these functional mutations will give rise to enzymes whose half lives at 65° C. are approximately 8-fold greater than that of wild type subtilisin E, provided no new deleterious mutations are introduced into these genes during the recombination process. Furthermore, the overall point mutagenesis rate associated with the recombination process can be estimated from the catalytic activity profile of a small sampling of the recombined variant library. If the point mutagenesis rate is zero, 25% of the population should exhibit wild type-like activity, 25% of the population should have double mutant (N181D+N218S)-like activity and the remaining 50% should have single mutant (N181D or N218S)-like activity. Finite point mutagenesis increases the fraction of the library that encodes enzymes with wild-type like (or lower) activity. This fraction can be used to estimate the point mutagenesis rate.

TABLE 1 DNA and amino acid substitutions in thermostable subtilisin E mutants R1 and R2. Base Position Amino acid Gene Base Substitution in codon Amino acid substitution R1 780 A→G 2 109 Asn→Ser 1107  A→G 2 218 Asn→Ser 1141  A→T 3 229 synonymous 1153  A→G 3 233 synonymous R2 484 A→G 3  10 synonymous 520 A→T 3  22 synonymous 598 A→G 3  48 synonymous 731 G→A 1  93 Val→Ile 745 T→C 3  97 synonymous 780 A→G 2 109 Asn→Ser 995 A→G 1 181 Asn→Asp 1189  A→G 3 245 synonymous Mutations listed are relative to wild type subtilisin E with base substitution at 780 in common.

MATERIALS AND METHODS Procedure for Defined Primer Based Recombination Using Two Flanking Primers

Two defined primers, P5N (5′-CCGAG CGTTG CATAT GTGGA AG-3′ (SEQ. ID. NO: 1), underlined sequence is NdeI restriction site) and P3B (5′-CGACT CTAGA GGATC CGATT C-3′ (SEQ. ID. NO: 2), underlined sequence is BamHI restriction site), corresponding to 5′ and 3′ flanking primers, respectively, were used for recombination. Conditions (100 ul final volume): 0.15 pmol plasmid DNA containing genes R1 and R2 (mixed at 1:1) were used as template, 15 pmol of each flanking primer, 1 times Taq buffer, 0.2 mM of each dNTP, 1.5 mM MgCl₂ and 0.25 U Taq polymerase. Program: 5 minutes of 95° C., 80 cycles of 30 seconds 94° C., 5 seconds 55° C. The product of correct size (approximately 1 kb) was cut from an 0.8% agarose gel after electrophoresis and purified using QIAEX II gel extraction kit. This purified product was digested with NdeI and BamHI and subcloned into pBE3 shuttle vector. This gene library was amplified in E. coli HB101 and transferred into B. subtilis DB428 competent cells for expression and screening, as described elsewhere (35).

DNA sequencing

Genes were purified using QIAprep spin plasmid miniprep kit to obtain sequencing quality DNA. Sequencing was done on an ABI 373 DNA Sequencing System using the Dye Terminator Cycle Sequencing kit (Perkin-Elmer, Branchburg, N.J.).

RESULTS

The progress of the staggered extension was monitored by removing aliquots (10 ul) from the reaction tube at various time points in the primer extension process and separating DNA fragments by agarose gel electrophoresis. Gel electrophoresis of primer extension reactions revealed that annealing/extension reactions of 5 seconds at 55° C. resulted in the occurrence of a smear approaching 100 bp (after 20 cycles), 400 bp (after 40 cycles), 800 bp (after 60 cycles) and finally a strong approximately 1 kb band within this smear. This band (mixture of reassembled products) was gel purified, digested with restriction enzyme BarnHT and NdeI, and ligated with vector generated by BamHI-NdeI digestion of the E. coli/B. subtilis pBE3 shuttle vector. This gene library was amplified in E. coli HB101 and transferred into B. subtilis DB428 competent cells for expression and screening (35).

The thermostability of enzyme variants was determined in the 96-well plate format described previously (33). About 200 clones were screened, and approximately 25% retained subtilisin activity. Among these active clones, the frequency of the double mutant-like phenotype (high thermostability) was approximately 23%, the single mutant-like phenotype was approximately 42%, and wild type-like phenotype was approximately 34%. This distribution is very close to the values expected when the two thermostable mutations N218S and N181D can recombine with each other completely freely.

Twenty clones were randomly picked from E. coli HB101 gene library. Their plasmid DNAs were isolated and digested with NdeI and BamHI. Nine out of 20 (45%) had the inserts of correct size (approximately 1 kb). Thus, approximately 55% of the above library had no activity due to lack of the correct subtilisin E gene. These clones are not members of the subtilisin library and should be removed from our calculations. Taking into account this factor, we find that 55% of the library (25% active clones/45% clones with correct size insert) retained subtilisin activity. This activity profile indicates a point mutagenesis rate of less than 2 mutations per gene (36). Five clones with inserts of the correct size were sequenced. The results are summarized in FIG. 4. All five genes are recombination products with minimum crossovers varying from 1 to 4. Only one new point mutation was found in these five genes.

EXAMPLE 2 Use of Defined Flanking Primers and Staggered Extension to Recombine pNB Esterase Mutants

The two-primer recombination method used here for pNB esterase is analogous to that described in Example 1 for subtilisin E. Two template pNB esterase mutant genes that differ at 14 bases are used. Both templates (61C7 and 4G4) are used in the plasmid form. Both target genes are present in the extension reaction at a concentration of 1 ng/ul. Flanking primers (RM1A and RM2A, Table 2) are added at a final concentration of 2 ng/ul (approximately 200-fold molar excess over template).

TABLE 2 Primers used in the recombination of the pNB esterase genes Primer Sequence RM1A GAG CAC ATC AGA TCT ATT AAC (SEQ. ID. NO: 3) RM2A GGA GTG GCT CAC AGT CGG TGG (SEQ. ID. NO: 4)

Clone 61C7 was isolated based on its activity in organic solvent and contains 13 DNA mutations vs. the wild-type sequence. Clone 4G4 was isolated for thermostability and contains 17 DNA mutations when compared with wild-type. Eight mutations are shared between them, due to common ancestry. The gene product from 4G4 is significantly more thermostable than the gene product from 61C7. Thus, one measure of recombination between the genes is the co-segregation of the high solvent activity and high thermostability or the loss of both properties in the recombined genes. In addition, recombination frequency and mutagenic rate can be ascertained by sequencing random clones.

For the pNB esterase gene, primer extension proceeds through 90 rounds of extension with a thermocycle consisting of 30 seconds at 94° C. followed by 15 seconds at 55° C. Aliquots (10 μl) are removed following cycle 20, 40, 60, 70, 80 and 90. Agarose gel electrophoresis reveals the formation of a low molecular weight ‘smear’ by cycle 20, which increases in average size and overall intensity at each successive sample point. By cycle 90, a pronounced smear is evident extending from 0.5 kb to 4 kb, and exhibiting maximal signal intensity at a size of approximately 2 kb (the length of the full length genes). The jump from half-length to full length genes appears to occur between cycles 60 and 70.

The intense smear is amplified through 6 cycles of polymerase chain reaction to more clearly define the full length recombined gene population. A minus-primer control is also amplified with flanking primers to determine the background due to residual template in the reaction mix. Band intensity from the primer extended gene population exceeds that of the control by greater than 10-fold, indicating that amplified, non-recombined template comprise only a small fraction of the amplified gene population.

The amplified recombined gene pool is digested with restriction enzymes XbaI and BamHI and ligated into the pNB106R expression vector described by Zock et al. (35). Transformation of ligated DNA into E. coli strain TG1 is done using the well characterized calcium chloride transformation procedure. Transformed colonies are selected on LB/agar plates containing 20 μg/ml tetracycline.

The mutagenic rate of the process is determined by measuring the percent of clones expressing an active esterase (20). In addition, colonies picked at random are sequenced and used to define the mutagenic frequency of the method and the efficiency of recombination.

EXAMPLE 3 Recombination of pNB Esterase Genes Using Interspersed Internal Defined Primers and Staggered Extension

This example demonstrates that the interspersed defined primer recombination technique can produce novel sequences through point mutagenesis and recombination of mutations present in the parent sequences.

Experimental design and background information

Two pNB esterase genes (2-13 and 5-B12) were recombined using the defined primer recombination technique. Gene products from both 2-13 and 5-B12 are measurably more thermostable than wild-type. Gene 2-13 contains 9 mutations not originally present in, the wild-type sequence, while gene 5-B12 contains 14. The positions at which these two genes differ from one another are shown in FIG. 5.

Table 3 shows the sequences of the eight primers used in this example. Location (at the 5′ end of the template gene) of oligo annealing to the template genes is indicated in the table, as is primer orientation (F indicates a forward primer, R indicates reverse). These primers are shown as arrows along gene 2-13in FIG. 5.

TABLE 3 Sequences of primers used in this example name orientation location sequence RM1A F −76 GAGCACATCAGATCTATTAAC (SEQ. ID. NO: 3) RM2A R +454 GGAGTGGCTCACAGTCGGTGG (SEQ. ID. NO: 4) S2 F 400 TTGAACTATCGGCTGGGGCGG (SEQ. ID. NO: 5) S5 F 1000 TTACTAGGGAAGCCGCTGGCA (SEQ. ID. NO: 6) S7 F 1400 TCAGAGATTACGATCGAAAAC (SEQ. ID. NO: 7) S8 R 1280 GGATTGTATCGTGTGAGAAAG (SEQ. ID. NO: 8) S10 R 880 AATGCCGGAAGCAGCCCCTTC (SEQ. ID. NO: 9) S13 R 280 CACGACAGGAAGATTTTGACT (SEQ. ID. NO: 10)

MATERIALS AND METHODS Defined-primer Based Recombination

1. Preparation of genes to be recombined. Plasmids containing the genes to be recombined were purified from transformed TG1 cells using the Qiaprep kit (Qiagen, Chatsworth, Calif.). Plasmids were quantitated by UV is absorption and mixed 1:1 for a final concentration of 50 ng/ul.

2. Staggered extension PCR and reassembly. 4 μl of the plasmid mixture was used as template in a 100 μl standard reaction (1.5 mM MgCl₂, 50 mM KCl, 10 mM Tris-HCl pH 9.0, 0.1% Triton X-100, 0.2 mM dNTPs, 0.25 U Taq polymerase (Promega, Madison, Wis.)) which also contained 12.5 ng of each of the 8 primers. A control reaction which contained no primers was also assembled. Reactions were thermocycled through 100 cycles of 94° C., 30 seconds; 55° C., 15 seconds. Checking an aliquot of the reaction on an agarose gel at this point showed the product to be a large smear (with no visible product in the no primer control).

3. DpnI digestion of the templates. 1 μl from the assembly reactions was then digested with DpnI to remove the template plasmid. The 10 μl DpnI digest contained 1×NEBuffer 4 and 5 U DpnI (both obtained from New England Biolabs, Beverly, Mass.) and was incubated at 37° C. for 45 minutes, followed by incubation at 70° C. for 10 minutes to heat kill the enzyme.

4. PCR amplification of the reassembled products. The 10 μl digest was then added to 90 μl of a standard PCR reaction (as described in step 2) containing 0.4 μM primers 5b (ACTTAATCTAGAGGGTATTA) (SEQ. ID. NO: 11) and 3b (AGCCTCGCGGGATCCCCGGG) (SEQ. ID. NO: 12) specific for the ends of the gene. After 20 cycles of standard PCR (94° C., 30 seconds; 48° C., 30 seconds, 72° C., 1 minute) a strong band of the correct size (2 kb) was visible when the reaction was checked on an agarose gel, while only a very faint band was visible in the lane from the no-primer control. The product band was purified and cloned back into the expression plasmid pNB106R and transformed by electroporation into TG1 cells.

RESULTS

Four 96 well plates of colonies resulting from this transformation were assayed for pNB esterase initial activity and thermostability. Approximately 60% of the clones exhibited initial activity and thermostabilty within 20% of the parental gene values. Very few (10%) of the clones were inactive (less than 10% of parent initial activity values). These results suggest a low rate of mutagenesis. Four mutants with the highest thermostability values were sequenced. Two clones (6E6 and 6H 1) were the result of recombination between the parental genes (FIG. 5). One of the remaining two clones contained a novel point mutation, and one showed no difference from parent 5B12. The combination of mutations T99C and C204T in mutant 6E6 is evidence for a recombination event between these two sites. In addition, mutant 6H1 shows the loss of mutation A1072G (but the retention of mutations C1038T and T1310C), which is evidence for two recombination events (one between sites 1028 and 1072, and another between 1072 and 1310). A total of five new point mutations were found in the four genes sequenced.

EXAMPLE 4 Recombination of Two Thermostable Subtilisin E Variants Using Internal Defined Primers and Staggered Extension

This example demonstrates that the defined primer recombination technique can produce novel sequences containing new combinations of mutations present in the parent sequences. It further demonstrates the utility of the defined primer recombination technique to obtain further improvements in enzyme performance (here, thermostability). This example further shows that the defined primers can bias the recombination so that recombination appears most often in the portion of the sequence defined by the primers (inside the primers). Furthermore, this example shows that specific mutations can be introduced into the recombined sequences by using the appropriate defined primer sequence(s) containing the desired mutation(s).

Genes encoding two thermostable subtilisin E variants of Example 1 (R1 and R2) were recombined using the defined primer recombination procedure with internal primers. FIG. 6 shows the four defined internal primers used to generate recombined progeny genes from template genes R1 and R2 in this example. Primer P50F contains a mutation (A→T at base position 598) which eliminates a HindIII restriction site and simultaneously adds a new unique NheI site. This primer is used to demonstrate that specific mutations can also be introduced into the population of recombined sequences by specific design of the defined primer. Gene R2 also contains a mutation A→G at the same base position, which eliminates the HindIII site. Thus restriction analysis (cutting by NheI and HindIII) of random clones sampled from the recombined library will indicate the efficiency of recombination and of the introduction of a specific mutation via the mutagenic primer. Sequence analysis of randomly-picked (unscreened) clones provides further information on the recombination and mutagenesis events occurring during defined primer-based recombination.

MATERIALS AND METHODS Defined-primer Based Recombination

A version of the defined primer based recombination illustrated in FIG. 2 was carried out with the addition of StEP.

1. Preparation of genes to be recombined. About 10 ug of plasmids containing R1 and R2 gene were digested at 37° C. for 1 hour with NdeI and BamHI (30 U each) in 50 μl of 1×buffer B (Boehringer Mannheim, Indianapolis, Ind.). Inserts of approximately 1 kb were purified from 0.8% preparative agarose gels using QIAEX II gel extraction kit. The DNA inserts were dissolved in 10 mM Tris-HCl (pH 7.4). The DNA concentrations were estimated, and the inserts were mixed 1:1 for a concentration of 50 ng/ul.

2. Staggered extension PCR and reassembly. Conditions (100 ul final volume): about 100 ng inserts were used as template, 50 ng of each of 4 internal primers, 1×Taq buffer, 0.2 mM of each dNTP, 1.5 mM MgCl₂ and 0.25 U Taq polymerase. Program: 7 cycles of 30 seconds at 94° C., 15 seconds at 55° C., followed by another 10 cycles of 30 seconds at 94° C., 15 seconds at 55° C., 5 seconds at 72° C. (staggered extension), followed by 53 cycles of 30 seconds at 94° C., 15 seconds at 55° C., 1 minute at 72° C. (gene assembly).

3. DpnI digestion of the templates. 1 μl of this reaction was diluted up to 9.5 μl with dH₂O and 0.5 μl of DpnI restriction enzyme was added to digest the DNA template for 45 minutes, followed by incubation at 70° C. for 10 minutes and then this 10 ul was used as template in a 10-cycle PCR reaction.

4. PCR amplification of reassembled products. PCR conditions (100 μl final volume): 30 pmol of each outside primer P5N and P3B, 1×Taq buffer, 0.2 mM of each dNTP and 2.5 U of Taq polymerase. PCR program: 10 cycles of 30 seconds at 94° C., 30 seconds at 55° C., 1 minute at 72° C. This program gave a single band at the correct size. The product was purified and subcloned into pBE3 shuttle vector. This gene library was amplified in E. coli HB101 and transferred into B. subtilis DB428 competent cells for expression and screening, as described elsewhere (35). Thermostability of enzyme variants was determined in the 96-well plate format described previously (33).

DNA sequencing

Ten E. coli HB101 transformants were chosen for sequencing. Genes were purified using QIAprep spin plasmid miniprep kit to obtain sequencing quality DNA. Sequencing was done on an ABI 373 DNA Sequencing System using the Dye Terminator Cycle Sequencing kit (Perkin-Elmer, Branchburg, N.J.).

RESULTS

1) restriction analysis:

Forty clones randomly picked from the recombined library were digested with restriction enzymes NheI and BamHI. In a separate experiment the same forty plasmids were digested with HindIII and BamHI. These reaction products were analyzed by gel electrophoresis. As shown in FIG. 7, eight out of 40 clones (approximately 20%) contain the newly introduced NheI restriction site, demonstrating that the mutagenic primer has indeed been able to introduce the specified mutation into the population.

2) DNA sequence analysis

The first ten randomly picked clones were subjected to sequence analysis, and the results are summarized in FIG. 8. A minimum of 6 out of the 10 genes have undergone recombination. Among these 6 genes, the minimal crossover events (recombination) between genes R1 and R2 vary from 1 to 4. All visible crossovers occurred within the region defined by the four primers. Mutations outside this region are rarely, if ever, recombined, as shown by the fact that there is no recombination between the two mutations at base positions 484 and 520. These results show that the defined primers can bias recombination so that it appears most often in the portion of the sequence defined by the primers (inside the primers). Mutations very close together also tend to remain together (for example, base substitutions 731 and 745 and base substitutions 1141 and 1153 always remain as a pair). However, the sequence of clone 7 shows that two mutations as close as 33 bases apart can be recombined (base position at 1107 and 1141).

Twenty-three new point mutations were introduced in the ten genes during the process. This error rate of 0.23% corresponds to 2-3 new point mutations per gene, which is a rate that has been determined optimal for generating mutant libraries for directed enzyme evolution (15). The mutation types are listed in Table 4. Mutations are mainly transitions and are evenly distributed along the gene.

TABLE 4 New point mutations identified in ten recombined genes Transition Frequency Transversion Frequency G→A 4 A→T 1 A→G 4 A→G 1 C→T 3 C→A 1 T→C 5 C→G 0 G→C 1 G→T 0 T→A 3 T→G 0 A total of 9860 bases were sequenced. The mutation rate was 0.23%

4) Phenotypic analysis

Approximately 450 B. subtilis DB428 clones were picked and grown in SG medium supplemented with 20 ug/ml kanamycin in 96-well plates. Approximately 56% of the clones expressed active enzymes. From previous experience, we know that this level of inactivation indicates a mutation rate on the order of 2-3 mutations per gene (35). Approximately 5% clones showed double mutant (N181D+N218S)-like phenotypes (which is below the expected 25% value for random recombination alone due primarily to point mutagenesis). (DNA sequencing showed that two clones, 7 and 8, from the ten randomly picked clones contain both N218S and N181D mutations.)

EXAMPLE 5 Optimization of the Actinoplanes utahensis ECB Deacylase by the Random-priming Recombination Method

In this example, the method is used to generate short DNA fragments from denatured, linear, double-stranded DNA (e.g., restriction fragments purified by gel electrophoresis; 22). The purified DNA, mixed with a molar excess of primers, is denatured by boiling, and synthesis is then carried out using the Klenow fragment of E. coli DNA polymerase I. This enzyme lacks 5′→3′ exonuclease activity, so that the random priming product is synthesized exclusively by primer extension and is not degraded by exonuclease. The reaction is carried out at pH 6.6, where the 3′→5′ exonuclease activity of the enzyme is much reduced (36). These conditions favor random initiation of synthesis.

The procedure involves the following steps:

1. Cleave the DNA of interest with appropriate restriction endonuclease(s) and purify the DNA fragment of interest by gel electrophoresis using Wizard PCR Prep Kit (Promega, Madison, Wis.). As an example, the Actinoplanes utahensis ECB deacylase gene was cleaved as a 2.4 kb-long Xho I-Psh AI fragment from the recombinant plasmid pSHP100. It was essential to linearize the DNA for the subsequent denaturation step. The fragment was purified by agarose gel electrophoresis using the Wizard PCR Prep Kit (Promega, Madison, Wis.) (FIG. 9, step (a)). Gel purification was also essential in order to remove the restriction endonuclease buffer from the DNA, since the Mg²⁺ ions make it difficult to denature the DNA in the next step.

2. 400 ng (about 0.51 pmol) of the double-stranded DNA dissolved in H₂O was mixed with 2.75 μg (about 1.39 nmol) of dp(N)₆ random primers. After immersion in boiling water for 3 minutes, the mixture was placed immediately in an ice/ethanol bath.

The size of the random priming products is an inverse function of the concentration of primer (33). The presence of high concentrations of primer is thought to lead to steric hindrance. Under the reaction conditions described here the random priming products are approximately 200-400 bp, as determined by electrophoresis through an alkaline agarose gel (FIG. 9 step b).

3. Ten μl of 10×reaction buffer [10×buffer: 900 mM HEPES, pH 6.6; 0.1 M magnesium chloride, 10 mM dithiothreitol, and 5 mM each dATP, dCTP, dGTP and dTTP) was added to the denatured sample, and the total volume of the reaction mixture was brought up to 95 μl with H₂O.

4. Ten units (about 5 μl) of the Klenow fragment of E.coli DNA polymerase I was added. All the components were mixed by gently tapping the outside of the tube and were centrifuged at 12,000 g for 1-2 seconds in a microfuge to move all the liquid to the bottom. The reaction was carried out at 22° C. for 35 minutes.

The rate of the extension depends upon the concentrations of the template and the four nucleotide precursors. Because the reaction was carried out under conditions that minimize exonucleolytic digestion, the newly synthesized products were not degraded to a detectable extent.

5. After 35 minutes at 22° C., the reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

6. The random primed products were purified by passing the whole reaction mixture through Centricon-100 (to remove the template and proteins) and Centricon-10 filters (to remove the primers and fragments less than 50 bases), successively. Centricon filters are available from Amicon Inc (Berverly, Mass.). The retentate fraction (about 85 μl in volume) was recovered from Centricon-10. This fraction contained the desired random priming products (FIG. 9, step c) and was used for whole gene reassembly.

Reassembly of the whole gene was accomplished by the following steps:

1. For reassembly by PCR, 5 μl of the random-primed DNA fragments from Centricon-10, 20 μl of 2×PCR pre-mix (5-fold diluted cloned Pfu buffer, 0.5 mM each dNTP, 0.1 U/ul cloned Pfu polymerase (Stratagene, La Jolla, Calif.)), 8 μl of 30% (v/v) glycerol and 7 μl of H₂O were mixed on ice. Since the concentration of the random-primed DNA fragments used for reassembly is the most important variable, it is useful to set up several separate reactions with different concentrations to establish the preferred concentration.

2. After incubation at 96° C. for 6 minutes, 40 thermocycles were performed, each with 1.5 minutes at 95° C., 1.0 minutes at 55° C. and 1.5 minutes+5 second/cycle at 72° C., with the extension step of the last cycle proceeding at 72° C. for 10 minutes, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus without adding any mineral oil. 3. 3 μl aliquots at cycles 20, 30 and 40 were removed from the reaction mixture and analyzed by agarose gel electrophoresis. The reassembled PCR product at 40 cycles contained the correct size product in a smear of larger and smaller sizes (see FIG. 9, step d).

The correctly reassembled product of this first PCR was further amplified in a second PCR reaction which contained the PCR primers complementary to the ends of the template DNA. The amplification procedure was as follows:

1. 2.0 μl of the PCR reassembly aliquots were used as template in 100-μl standard PCR reactions, which contained 0.2 mM each primers of xhoF28 (5′ GGTAGAGCGAGTCTCGAGGGGGAGATGC3′) (SEQ. ID. NO: 13) and pshR22 (5′ AGCCGGCGTGACGTGGGTCAGC 3′) (SEQ. ID. NO: 14), 1.5 mM MgCl₂, 10 mM Tris-HCl [pH 9.0], 50 mM KCl, 200 μM each of the four dNTPs, 6% (v/v) glycerol, 2.5 U of Taq polymerase (Promega, Madison, Wis.) and 2.5 U of Pfu polymerase (Stratagene, La Jolla, Calif.).

2. After incubation at 96° C. for 5 minutes, 15 thermocycles were performed, each with 1.5 minutes at 95° C., 1.0 minutes at 55° C. and 1.5 minutes at 72° C., followed by additional 15 thermocycles of 1.5 minutes at 95° C., 1.0 minutes at 55° C. and 1.5 minutes+5 second/cycle at 72° C. with the extension step of the last cycle proceeding at 72° C. for 10 minutes, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus without adding any mineral oil.

3. The amplification resulted in a large amount of PCR product with the correct size of the ECB deacylase whole gene (FIG. 9, step e).

Cloning was accomplished as follows:

1. The PCR product of ECB deacylase gene was digested with Xho I and Psh AI restriction enzymes, and cloned into a modified pIJ702 vector.

2. S. lividans TK23 protoplasts were transformed with the above ligation mixture to form a mutant library.

In situ screening the ECB deacylase mutants

Each transformant within the S. lividans TK23 library obtained as described above was screened for deacylase activity with an in situ plate assay method using ECB as substrate. Transformed protoplasts were allowed to regenerate on R2YE agar plates by incubation at 30° C. for 24 hours and to develop in the presence of thiostrepton for further 48-72 hours. When the colonies grew to proper size, 6 ml of 45° C. purified-agarose (Sigma) solution containing 0.5 mg/ml ECB in 0.1 M sodium acetate buffer (pH 5.5) was poured on top of each R2YE-agar plate and allowed to further develop for 18-24 hours at 37° C. Colonies surrounded by a clearing zone larger than that of a control colony containing wild-type recombinant plasmid pSHP150-2 were indicative of more efficient ECB hydrolysis resulting from improved enzyme properties or improved enzyme expression and secretion level, and were chosen as potential positive mutants. These colonies were picked for subsequent preservation and manipulation.

HPLC assay of the ECB deacylase mutants

Single positive transformants were inoculated into 20 ml fermentation medium containing 5 μg/ml thiostrepton and allowed to grow at 30° C. for 48 hours. At this step, all cultures were subjected to HPLC assay using ECB as substrate. 100 μl of whole broth was used for an HPLC reaction at 30° C. for 30 minutes in the presence of 0.1 M NaAc (pH 5.5), 10% (v/v) MeOH and 200 μg/ml of ECB substrate. 20 μl of each reaction mixture was loaded onto a PolyLC polyhydroxyethyl aspartamide column (4.6×100 mm) and eluted by acetonitrile gradient at a flow rate of 2.2 ml/min. The ECB-nucleus was detected at 225 nm.

Purification of the ECB deacylase mutants

After the HPLC assay, 2.0 ml pre-cultures of all potential positive mutants were then used to inoculate 50-ml fermentation medium and allowed to grow at 30° C., 280 rpm for 96 hours. These 50-ml cultures were then centrifuged at 7,000 g for 10 minutes. The supernatants were re-centrifuged at 16,000 g for 20 minutes. The supernatants containing the ECB deacylase mutant enzymes were stored at −20° C.

The supernatants from the positive mutants were further concentrated to {fraction (1/30)} their original volume with an Amicon filtration unit with molecular weight cutoff of 10 kD. The resulting enzyme samples were diluted with an equal volume of 50 mM KH₂PO₄ (pH 6.0) buffer and 1.0 ml was applied to Hi-Trap ion exchange column. The binding buffer was 50 mM KH₂PO₄ (pH 6.0), and the elution buffer was 50 mM KH₂PO₄ (pH 6.0) and 1.0 M NaCl. A linear gradient from 0 to 1.0 M NaCl was applied in 8 column volumes with a flow rate of 2.7 ml/min. The ECB deacylase mutant fraction eluted at 0.3 M NaCl and was concentrated and buffer exchanged into 50 mM KH₂PO₄ (pH 6.0) in Amicon Centricon-10 units. Enzyme purity was verified by SDS-PAGE, and the concentration was determined using the Bio-Rad Protein Assay.

Specific activity assay of the ECB deacylase mutants

4.0 μg of each purified ECB deacylase mutant was used for the activity assay at 30° C. for 0-60 minutes in the presence of 0.1 M NaAc (pH 5.5), 10% (v/v) MeOH and 200 μg/ml of ECB substrate. 20 μl of each reaction mixture was loaded onto a PolyLC polyhydroxyethyl aspartamide column (4.6×100 mm) and eluted with an acetonitrile gradient at a flow rate of 2.2 ml/min. The reaction products were monitored at 225 nm and recorded on an IBM PC data acquisition system. The ECB nucleus peak was numerically integrated and used to calculate the specific activity of each mutant.

As shown in FIG. 10, after only one round of applying this random-priming based technique on the wild-type ECB deacylase gene, one mutant (M16) from 2,012 original transformants was found to possess 2.4 times the specific activity of the wild-type enzyme. FIG. 11 shows that the activity of M16 has been increased relative to that of the wild-type enzyme over a broad pH range.

The nucleotide sequence which encodes the M16 mutant gene is set forth in SEQ. ID. NO: 26. The nucleotide sequence for the wild-type ECB deacylase gene is set forth in SEQ. ID. NO: 31.

Other mutant genes which were isolated utilizing the above method include mutant M2#7, M2#14, M15 and M20. The nucleotide sequences for these mutant genes are set forth in SEQ. ID. NOS: 27, 28, 29 and 30, respectively. The amino acid sequences for the ECB deacylases encoded by the mutant genes are set forth in SEQ. ID. NOS: 32 (M16); 33 (M2#7); 34 (M2#14); 35 (M15); and 36 (M20).

The above-identified mutant genes may be ligated into a suitable expression vector and incorporated into a host cell or organism for expression. The resulting ECB deacylase enzyme which is expressed by the transformed host cell or organism may be isolated, purified and used as an enzyme in a wild variety of synthetic protocols which require the ECB deacylase enzyme. Alternatively, the transformed host cell or organism may be incorporated directly into suitable production broths where the ECB deacylase enzyme is generated in situ by the transformant.

EXAMPLE 6 Improving the Thermostability Bacillus subtilis Subtilisin E Using the Random-sequence Primer Recombination Method

This example demonstrates the use of various DNA polymerases for primer-based recombination. It further demonstrates the stabilization of subtilisin E by recombination.

Genes R1 and R2 encoding the two thermostable subtilisin E variants described in Example 1 were chosen as the templates for recombination.

(1) Target gene preparation

Subtilisin E thermostable mutant genes R1 and R2 (FIG. 11) were subjected to random primed DNA synthesis. The 986-bp fragment including 45 nt of subtilisin E prosequence, the entire mature sequence and 113 nt after the stop codon were obtained by double digestion of plasmid pBE3 with Bam HI and Nde I and purified from a 0.8% agarose gel using the Wizard PCR Prep Kit (Promega, Madison, Wis.). It was essential to linearize the DNA for the subsequent denaturation step. Gel purification was also essential in order to remove the restriction endonuclease buffer from the DNA, since the Mg²⁺ ions make it difficult to denature the DNA in the next step.

(2) Random primed DNA synthesis

Random primed DNA synthesis used to generate short DNA fragments from denatured, linear, double-stranded DNA. The purified B. subtilis subtilisin E mutant genes, mixed with a molar excess of primers, were denatured by boiling, and synthesis was then carried out using one of the following DNA polymerases: the Klenow fragment of E. coli DNA polymerase I, bacteriophage T4 DNA polyrmerase and T7 sequenase version 2.0 DNA polymerase.

Under its optimal performance conditions (29), bacteriophage T4 DNA polymerase gives similar synthesis results as the Klenow fragment does. When T7 sequenase version 2.0 DNA polymerase (31, 32) is used, the lengths of the synthesized DNA fragments are usually larger. Some amount of MnCl₂ has to be included during the synthesis in order to control the lengths of the synthesized fragments within 50-400 bases.

Short, nascent DNA fragments can also be generated with PCR using the Stoffel fragment of Taq DNA polymerase or Pfu DNA polymerase. An important consideration is to identify by routine experimentation the reaction conditions which ensure that the short random primers can anneal to the templates and give sufficient DNA amplification at higher temperatures. We have found that random primers as short as dp(N)₁₂ can be used with PCR to generate fragments.

2.1 Random primed DNA synthesis with the Klenow fragment

The Klenow fragment of E. coli DNA polymerase I lacks 5′→3′ exonuclease activity, so that the random priming product is synthesized exclusively by primer extension and is not degraded by exonuclease. The reaction was carried out at pH 6.6, where the 3′→5′ exonuclease activity of the enzyme is much reduced (36). These conditions favor random initiation of synthesis.

1. 200 ng (about 0.7 pmol) of R1 DNA and equal amount of R2 DNA dissolved in H₂O was mixed with 13.25 μg (about 6.7 nmol) of dp(N)₆ random primers. After immersion in boiling water for 5 minutes, the mixture was placed immediately in an ice/ethanol bath.

The size of the random priming products is an inverse function of the concentration of primer (30). The presence of high concentrations of primer is thought to lead to steric hindrance. Under the reaction conditions described here the random priming products are approximately 50-500 bp, as determined by agarose gel electrophoresis.

2. Ten μl of 10×reaction buffer [10×buffer: 900 mM HEPES, pH 6.6; 0.1 M magnesium chloride, 20 mM dithiothreitol, and 5 mM each dATP, dCTP, dGTP and dTTP) was added to the denatured sample, and the total volume of the reaction mixture was brought up to 95 μl with H₂O.

3. Ten units (about 5 μl) of the Klenow fragment of E. coli DNA polymerase I (Boehringer Mannheim, Indianapolis, Ind.) was added. All the components were mixed by gently tapping the outside of the tube and were centrifuged at 12,000 g for 1-2 seconds in a microfuge to move all the liquid to the bottom. The reaction was carried out at 22° C. for 3 hours.

The rate of the extension depends upon the concentrations of the template and the four nucleotide precursors. Because the reaction was carried out under conditions that minimize exonucleolytic digestion, the newly synthesized products were not degraded to a detectable extent.

4. After 3 hours at 22° C., the reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

5. The random primed products were purified by passing the whole reaction mixture through Microcon-100 (Amicon, Beverly Mass.) (to remove the template and proteins) and Microcon-10 filters (to remove the primers and fragments less than 40 bases), successively. The retentate fraction (about 65 μl in volume) was recovered from the Microcon-10. This fraction containing the desired random priming products was buffer-exchanged against PCR reaction buffer with the new Microcon-10 further use in whole gene reassembly.

2.2 Random primed DNA synthesis with bacteriophage T4 DNA polymerase

Bacteriophage T4 DNA polymerase and the Klenow fragment of E. coli DNA polymerase I are similar in that each possesses a 5′-3′ polymerase activity and a 3′-5′ exonuclease activity. The exonucleases activity of bacteriophage T4 DNA polymerase is more than 200 times that of the Klenow fragment. Since it does not displace the short oligonucleotide primers from single-stranded DNA templates (23), the efficiency of mutagenesis is different from the Klenow fragment.

1. 200 ng (about 0.7 pmol) of R1 DNA and equal amount of R2 DNA dissolved in H₂O was mixed with 13.25 μg (about 6.7 nmol) of dp(N)₆ random primers. After immersion in boiling water for 5 minutes, the mixture was placed immediately in an ice/ethanol bath. The presence of high concentrations of primer is thought to lead to steric hindrance.

2. Ten μl of 10×reaction buffer [10×buffer: 500 mM Tris-HCl, pH 8.8; 150 mM (NH₄)₂SO_(4; 70) mM magnesium chloride, 100 mM 2-mercaptoethanol, 0.2 mg/ml bovine serum albumin and 2 mM each dATP, dCTP, dGTP and dTTP) was added to the denatured sample, and the total volume of the reaction mixture was brought up to 90 μl with H₂O.

3. Ten units (about 10 μl) of the T4 DNA polymerase I (Boehringer Mannheim, Indianapolis, Ind.) was added. All the components were mixed by gently tapping the outside of the tube and were centrifuged at 12,000 g for 1-2 seconds in a microfuge to move all the liquid to the bottom. The reaction was carried out at 37° C. for 30 minutes. Under the reaction conditions described here the random priming products are approximately 50-500 bp.

4. After 30 minutes at 37° C., the reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

5. The random primed products were purified by passing the whole reaction mixture through Microcon-100 (to remove the template and proteins) and Microcon-10 filters (to remove the primers and fragments less than 40 bases), successively. The retentate fraction (about 65 μl in volume) was recovered from the Microcon-10. This fraction containing the desired random priming products was buffer-exchanged against PCR reaction buffer with the new Microcon-10 further use in whole gene reassembly.

2.3 Random primed DNA synthesis with the T7 sequenase v2.0 DNA polymerase

Since the T7 sequenase v2.0 DNA polymerase lacks exonuclease activity and is highly processive, the average length of DNA synthesized is greater than that of DNAs synthesized by the Klenow fragment or T4 DNA polymerase. But in the presence of proper amount of MnCl₂ in the reaction, the size of the synthesized fragments can be controlled to less than 400 bps.

1. 200 ng (about 0.7 pmol) of R1 DNA and equal amount of R2 DNA dissolved in H₂O was mixed with 13.25 μg (about 6.7 nmol) of dp(N)₆ random primers. After immersion in boiling water for 5 minutes, the mixture was placed immediately in an ice/ethanol bath. The presence of high concentrations of primer is thought to lead to steric hindrance.

2. Ten μl of 10×reaction buffer [10×buffer: 400 mM Tris-HCl, pH 7.5; 200 mM magnesium chloride, 500 mM NaCl, 3 mM MnCl₂, and 3 mM each dATP, dCTP, dGTP and dTTP) was added to the denatured sample, and the total volume of the reaction mixture was brought up to 99.2 μl with H₂O.

3. Ten units (about 0.8 μl) of the T7 Sequenase v2.0 (Amersham Life Science, Cleveland, Ohio) was added. All the components were mixed by gently tapping the outside of the tube and were centrifuged at 12,000 g for 1-2 seconds in a microfuge to move all the liquid to the bottom. The reaction was carried out at 22° C. for 15 minutes. Under the reaction conditions described here the random priming products are approximately 50-400 bps.

4. After 15 minutes at 22° C., the reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

5. The random primed products were purified by passing the whole reaction mixture through Microcon-100 (to remove the template and proteins) and Microcon-10 filters (to remove the primers and fragments less than 40 bases), successively. The retentate fraction (about 65 μl in volume) was recovered from the Microcon-10. This fraction containing the desired random priming products was buffer-exchanged against PCR reaction buffer with the new Microcon-10 further use in whole gene reassembly.

2.4 Random primed DNA synthesis with PCR using the Stoffel fragment of Taq DNA polymerase

Similar to the Klenow fragment of E. coli DNA polymerase I, the Stoffel fragment of Taq DNA polymerase lacks 5′ to 3′ exonuclease activity. It is also more thermostable than Taq DNA polymerase. The Stoffel fragment has low processivity, extending a primer an average of only 5-10 nucleotides before it dissociates. As a result of its lower processivity, it may also have improved fidelity.

1. 50 ng (about 0.175 pmol) of R1 DNA and equal amount of R2 DNA dissolved in H₂O was mixed with 6.13 μg (about 1.7 nmol) of dp(N)₁₂ random primers.

2. Ten μl of 10×reaction pre-mix [10×reaction pre-mix: 100 mM Tris-HCl, pH 8.3; 30 mM magnesium chloride, 100 mM KCl, and 2 mM each dATP, dCTP, dGTP and dTTP) was added, and the total volume of the reaction mixture was brought up to 99.0 μl with H₂O.

3. After incubation at 96° C. for 5 minutes, 2.5 units (about. 1.0 μl) of the Stoffel fragment of Taq DNA polymerase (Perkin-Elmer Corp., Norwalk, Conn.) was added. Thirty-five thermocycles were performed, each with 60 seconds at 95° C., 60 seconds at 55° C. and 50 seconds at 72° C., without the extension step of the last cycle, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus. Under the reaction conditions described here the random priming products are approximately 50-500 bp.

4. The reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

5. The random primed products were purified by passing the whole reaction mixture through Microcon-100 (to remove the template and proteins) and Microcon-10 filters (to remove the primers and fragments less than 40 bases), successively. The retentate fraction (about 65 μl in volume) was recovered from the Microcon-10. This fraction containing the desired random priming products was buffer-exchanged against PCR reaction buffer with the new Microcon-10 further use in whole gene reassembly.

2.5 Random primed DNA synthesis with PCR using Pfu DNA polymerase

Pfu DNA polymerase is extremely thermostable, and the enzyme possesses an inherent 3′ to 5′ exonuclease activity but does not possess a 5′→3′ exonuclease activity. Its base substitution fidelity has been estimated to be 2×10⁻⁶.

1. 50 ng (about 0.175 pmol) of R1 DNA and equal amount of R2 DNA dissolved in H₂O was mixed with 6.13mg (about 1.7 nmol) of dp(N)₁₂ random primers.

2. Fifty μl of 2×reaction pre-mix [2×reaction pre-mix: 5-fold diluted cloned Pfu buffer (Stratagene, La Jolla, Calif.), 0.4 mM each dNTP], was added, and the total volume of the reaction mixture was brought up to 99.0 μl with H₂O.

3. After incubation at 96° C. for 5 minutes, 2.5 units (about 1.0 μl) of Pfu DNA polymerase (Stratagene, La Jolla, Calif.) was added. Thirty-five thermocycles were performed, each with 60 seconds at 95° C., 60 seconds at 55° C. and 50 seconds at 72° C., without the extension step of the last cycle, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus. Under the reaction conditions described here the major random priming products are approximately 50-500 bp.

4. The reaction was terminated by cooling the sample to 0° C. on ice. 100 μl of ice-cold H₂O was added to the reaction mixture.

5. The random primed products were purified by passing the whole reaction mixture through Microcon-100 (to remove the template and proteins) and Microcon-10 filters (to remove the primers and fragments less than 40 bases), successively. The retentate fraction (about 65 μl in volume) was recovered from the Microcon-10. This fraction containing the desired random priming products was buffer-exchanged against PCR reaction buffer with the new Microcon-10 further use in whole gene reassembly.

(3) Reassembly of the whole gene

1. For reassembly by PCR, 10 μl of the random-primed DNA fragments from Microcon-10, 20 μl of 2×PCR pre-mix (5-fold diluted cloned Pfu buffer, 0.5 mM each dNTP, 0.1 U/μl cloned Pfu polymerase (Stratagene, La Jolla, Calif.)), 15 μl of H₂O were mixed on ice.

2. After incubation at 96° C. for 3 minutes, 40 thermocycles were performed, each with 1.0 minute at 95° C., 1.0 minute at 55° C. and 1.0 minute+5 second/cycle at 72° C., with the extension step of the last cycle proceeding at 72° C. for 10 minutes, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus without adding any mineral oil.

3. 3 μl aliquots at cycles 20, 30 and 40 were removed from the reaction mixture and analyzed by agarose gel electrophoresis. The reassembled PCR product at 40 cycles contained the correct size product in a smear of larger and smaller sizes.

(4) Amplification

The correctly reassembled product of this first PCR was further amplified in a second PCR reaction which contained the PCR primers complementary to the ends of the template DNA.

1. 2.0 μl of the PCR reassembly aliquots were used as template in 100-μl standard PCR reactions, which contained 0.3 mM each primers of P1 (5′ CCGAGCGTTGC ATATGTGGAAG 3′) (SEQ. ID. NO: 15) and P2 (5′ CGACTCTAGAGGATCCGATTC 3′) (SEQ. ID. NO: 16), 1.5 mM MgCl₂, 10 mM Tris-HCl [pH 9.0], 50 mM KCl, 200 mM each of the four dNTPs, 2.5 U of Taq polymerase (Promega, Madison, Wis., USA) and 2.5 U of Pfu polymerase (Stratagene, La Jolla, Calif.).

2. After incubation at 96° C. for 3 minutes, 15 thermocycles were performed, each with 60 seconds at 95° C., 60 seconds at 55° C. and 50 seconds at 72° C., followed by additional 15 thermocycles of 60 seconds at 95° C., 60 seconds at 55° C. and 50 seconds (+5 second/cycle) at 72° C. with the extension step of the last cycle proceeding at 72° C. for 10 minutes, in a DNA Engine PTC-200 (MJ Research Inc., Watertown, Mass.) apparatus without adding any mineral oil.

3. The amplification resulted in a large amount of PCR product with the correct size of the subtilisin E whole gene.

(5) Cloning

Since the short DNA fragments were generated with five different DNA polymerases, there were five pools of final PCR amplified reassembled products. Each of the DNA pool was used for constructing the corresponding subtilisin E mutant library.

1. The PCR amplified reassembled product was purified by Wizard DNA-CleanUp kit (Promega, Madison, Wis.), digested with Bam HI and Nde I, electrophoresed in a 0.8% agarose gel. The 986-bp product was cut from the gel and purified by Wizard PCR Prep kit (Promega, Madison, Wis.). Products were ligated with vector generated by Bam HI-Nde I digestion of the pBE3 shuttle vector.

2. E. coli HB101 competent cells were transformed with the above ligation mixture to form a mutant library. About 4,000 transformants from this library were pooled, and recombinant plasmid mixture was isolated from this pool.

3. B. subtilis DB428 competent cells were transformed with the above isolated plasmid mixture to form another library of the subtilisin E variants.

4. Based on the DNA polymerase used for random priming the short, nascent DNA fragments, the five libraries constructed here were named: library/Klenow, library/T4, library/Sequenase, library/Stoffel and library/Pfu. About 400 tranformants from each library were randomly picked and subjected to screening for thermostability [see Step (7)].

(6) Random clone sequencing

Ten random clones from the B. subtilis DB428 library/Klenow was chosen for DNA sequence analysis. Recombinant plasmids were individually purified from B. subtilis DB428 using a QlAprep spin plasmid miniprep kit (QIAGEN) with the modification that 2 mg/ml lysozyme was added to P1 buffer and the cells were incubated for 5 minutes at 37° C., retransformed into competent E. coli HB 101 and then purified again using QlAprep spin plasmid miniprep kit to obtain sequencing quality DNA. Sequencing was done on an ABI 373 DNA Sequencing System using the Dye Terminator Cycle Sequencing kit (Perkin-Elmer Corp., Norwalk, Conn.).

(7) Screening for thermostability

About 400 transformants from each of the five libraries described at Step (4) were subjected to screening. Screening was based on the assay described previously (33, 35), using succinyl-Ala-Ala-Pro-Phe-p-nitroanilide (SEQ. ID. NO: 25) as substrate. B. subtilis DB428 containing the plasmid library were grown on LB/kanamycin (20 μg/ml) plates. After 18 hours at 37° C. single colonies were picked into 96-well plates containing 100 μl SG/kanamycin medium per well. These plates were shaken and incubated at 37° C. for 24 hours to let the cells to grow to saturation. The cells were spun down, and the supernatants were sampled for the thermostability assay. Three replica 96-well assay plates were duplicated for each growth plate, with each well containing 10 ml of supernatant. The subtilisin activities were then measured by adding 100 ml of activity assay solution (0.2 mM succinyl-Ala-Ala-Pro-Phe-p-nitroanilide (SEQ. ID. NO: 25), 100 mM Tris-HCl, 10 mM CaCl₂, pH 8.0, 37° C.). Reaction velocities were measured at 405 nm over 1.0 min. in a ThermoMax microplate reader (Molecular Devices, Sunnyvale Calif.). Activity measured at room temperature was used to calculate the fraction of active clones (clones with activity less than 10% of that of wild type were scored as inactive). Initial activity (Ai) was measured after incubating one assay plate at 65° C. for 10 minutes by immediately adding 100 μl of prewarmed (37° C.) assay solution (0.2mM succinyl-Ala-Ala-Pro-Phe-p-nitroanilide (SEQ. ID. NO: 25), 100 mM Tris-HCl, pH 8.0, 10 mM CaCl₂) into each well. Residual activity (Ar) was measured after 40 minute incubation.

(8) Sequence Analysis

After screening, one clone that showed the highest thermostability within the 400 transformants from the library/Klenow was re-streaked on LB/kanamycin agar plate, and single colonies derived from this plate were inoculated into tube cultures, for glycerol stock and plasmid preparation. The recombinant plasmid was purified using a QlAprep spin plasmid miniprep kit (QIAGEN) with the modification that 2 mg/ml lysozyme was added to P1 buffer and the cells were, incubated for 5 minutes at 37° C., retransformed into competent E. coli HB 101 and then purified again using QlAprep spin plasmid miniprep kit to obtain sequencing quality DNA. Sequencing was done on an ABI 373 DNA Sequencing System using the Dye Terminator Cycle Sequencing kit (Perkin-Elmer Corp., Norwalk, Conn.).

RESULTS 1. Recombination Frequency and Efficiency Associated with the Random-sequence Recombination

The random primed process was carried out as described above. The process is illustrated in FIG. 1. Ten clones from the mutant library/Klenow were selected at random and sequenced. As summarized in FIG. 12 and Table 5, all clones were different from the parent genes. The frequency of occurrence of a particular point mutation from parent R1 or R2 in the recombined genes ranged from 40% to 70%, fluctuating around the expected value of 50%. This indicates that the two parent genes have been nearly randomly recombined with the random primer technique. FIG. 12 also shows that all ten mutations can be recombined or dissected, even those that are only 12 bp apart.

We then estimated the rates of subtilisin thermoinactivation at 65° C. by analyzing the 400 random clones from each of the five libraries constructed at Step (5). The thermostabilities obtained from one 96-well plate are shown in FIG. 13, plotted in descending order. Approximately 21% of the clones exhibited thermostability comparable to the mutant with the N181D and N218S double mutations. This indicates that the N181D mutation from RC2 and the N218S mutation from RC1 have been randomly recombined. Sequence analysis of the clone exhibiting the highest thermostability among the screened 400 transformants from the library/Klenow showed the mutation N181D and N218S did exist.

2. Frequency of Newly Introduced Mutations During the Random Priming Process

Approximately 400 transformants from each of the five B. sublilis DB428 libraries [see Step (5)] were picked, grown in SG medium supplemented with 20 ug/ml kanamycin in 96-well plates and subjected to subtilisin E activity screening. Approximately 77-84% of the clones expressed active enzymes, while 16-23% of the transformants were inactive, presumably as a result of newly introduced mutations. From previous experience, we know that this rate of inactivation indicates a mutation rate on the order of 1 to 2 mutations per gene (35).

As shown in FIG. 12, 18 new point mutations were introduced in the process. This error rate of 0.18% corresponds to 1-2 new point mutations per gene, which is a rate that has been determined from the inactivation curve. Mutations are nearly randomly distributed along the gene.

TABLE 5 DNA and amino acid residue substitutions in the ten random clones from Library/Klenow Base Substitution Amino Acid Substitution Clone # Position Substitution Type Substitution Type C #1 839 A→C transversion Gly→Gly synonymous C #2 722 A→G transition Ser→Ser synonymous C #2 902 T→C transition Val→Val synonymous C #2 1117  C→G transversion Ser→Ser synonymous C #4 809 T→C transition Asn→Asn synonymous C #4 1098  G→C transversion Gly→Ala non-synonymous C #4 1102  T→C transition Ala→Ala synonymous C #6 653 C→A transversion His→Ile non-synonymous C #6 654 A→T transversion His→Ile non-synonymous C #6 657 T→C transition Val→Ala non-synonymous C #6 658 A→C transversion Val→Ala non-synonymous C #6 1144  A→G transition Ala→Ala synonymous C #6 1147  A→G transition Ala→Ala synonymous C #7 478 T→C transition Ile→IIe synonymous C #9 731 A→G transition Ala→Ala synonymous C #9 994 A→G transition Val→Val synonymous  C #10 1111  A→G transition Gly→Gly synonymous  C #10 1112  A→T transversion Thr→Ser non-synonymous

The mutation types are listed in TABLE 5. The direction of mutation is clearly nonrandom. For example, A changes more often to G than to either T or C. All transitions, and in particular T-C and A-G, occur more often than transversion. Some nucleotides are more mutable than others. One G→C, one C→G and one C→A transversions were found within the 10 sequenced clones. These mutations were generated very rarely during the error-prone PCR mutagenesis of subtilisin (37). Random-priming process may allow access to a greater range of amino acid substitutions than PCR-based point mutagenesis.

It is interesting to note that a short stretch of 5′ C GGT ACG CAT GTA GCC GGT ACG 3′ (SEQ. ID. NO: 16) at the position 646-667 in parents R1 and R2 was mutated to 5′ C GGT ACG ATT GCC GCC GGT ACG 3′ (SEQ. ID. NO: 17) in random clone C#6. Since the stretch contains two short repeats at the both ends, the newly introduced mutations may result from a splipped-strand mispairing process instead of point-mutation only process. Since there is no frame-shift, this kind of slippage may be useful for domain conversion.

3. Comparison of Different DNA Polymerase Fidelity in the Random-priming Process

During random-priming recombination, homologous DNA sequences are nearly randomly recombined and new point mutations are also introduced. Though these point mutations may provide useful diversity for some in vitro evolution applications, they are problematic recombination of beneficial mutations already identified previously, especially when the mutation rate is this high. Controlling error rate during random priming process is particularly important for successfully applying this technique to solve in vitro evolution problems. By choosing different DNA polymerase and modifying the reaction conditions, the random priming molecular breeding technique can be adjusted to generate mutant libraries with different error rates.

The Klenow fragment of E. coli DNA polymerase I, bacteriophage T4 DNA polymerase, T7 sequenase version 2.0 DNA polymerase, the Stoffel fragment of Taq polymerase and Pfu polymerase have been tested for the nascent DNA fragment synthesis. The activity profiles of the resulting five populations [see Step (5)] are shown in FIG. 13. To generate these profiles, activities of the individual clones measured in the 96-well plate screening assay are plotted in descending order. The Library/Stoffel and Library/Klenow contain higher percentage of wild-type or inactive subtilisin E clones than that of the Library/Pfu. In all five populations, percentage of the wild-type and inactive clones ranges from 17-30%.

EXAMPLE 7 Use of Defined Flanking Primers and Staggered Extension to Recombine Single Stranded DNA

This example demonstrates the use of the defined primer recombination with staggered extension in the recombination of single stranded DNA.

Method Description

Single-stranded DNA can be prepared by a variety of methods, most easily from plasmids using helper phage. Many vectors in current use are derived from filamentous phages, such as M13mp derivatives. After transformation into cells, these vectors can give rise both to new double-stranded circles and to single-stranded circles derived from one of the two strands of the vector. Single-stranded circles are packaged into phage particles, secreted from cells and can be easily purified from the culture supernatant.

Two defined primers (for example, hybridizing to 5′ and 3′ ends of the templates) are used here to recombine single stranded genes. Only one of the primers is needed before the final PCR amplification. Extended recombination primers are first generated by the staggered extension process (StEP), which consists of repeating cycles of denaturation followed by extremely abbreviated annealing/extension step(s). The extended fragments are then reassembled into full-length genes by thermocycling-assisted homologous gene assembly in the presence of a DNA polymerase, followed by a gene amplification step.

The progress of the staggered extension process is monitored by removing aliquots (10 ul) from the reaction tube (100 ul starting volume) at various time points in the primer extension and separating DNA fragments by agarose gel electrophoresis. Evidence of effective primer extension is seen as appearance of a low molecular weight ‘smear’ early in the process which increases in molecular weight with increasing cycle number. Initial reaction conditions are set to allow template denaturation (for example, 94° C. −30 second denaturation) followed by very brief annealing/extension step(s) (e.g. 55° C. −1 to 15 seconds) repeated through 5-20 cycle increments prior to reaction sampling. Typically, 20-200 cycles of staggered extension are required to generate single stranded DNA ‘smears’ corresponding to sizes greater than the length of the complete gene.

The experimental design is as in Example 1. Two thermostable subtilisin E mutants R1 and R2 gene are subcloned into vector M13mp18 by restriction digestion with EcoRI and BamHI. Single stranded DNA is prepared as described (39).

Two flanking primer based recombination

Two defined primers, P5N (5′-CCGAG CGTTG CATAT GTGGA AG-3′ (SEQ. ID. NO: 18), underlined sequence is NdeI restriction site) and P3B (5′-CGACT CTAGA GGATC CGATT C-3′ (SEQ. ID. NO: 19), underlined sequence is BamHI restriction site), corresponding to 5′ and 3′ flanking primers, respectively, are used for recombination. Conditions (100 ul final volume): 0.15 pmol single-stranded DNA containing R1 and R2 gene (mixed at 1:1) are used as template, 15 pmol of one flanking primer (either P5N or P3B), 1×Taq buffer, 0.2 mM of each dNTP, 1.5 mM MgCl₂ and 0.25 U Taq polymerase. Program: 5 minutes of 95° C., 80-200 cycles of 30 seconds at 94° C., 5 seconds at 55° C. The single-stranded DNA products of correct size (approximately 1 kb) are cut from 0.8% agarose gel after electrophoresis and purified using QIAEX II gel extraction kit. This purified product is amplified by a conventional PCR. Condition (100 ul final volume): 1-10 ng of template, 30 pmol of each flanking primer, 1×Taq buffer, 0.2 mM of each dNTP, 1.5 mM MgCl₂ and 0.25 U Taq polymerase. Program: 5 minutes at 95° C., 20 cycles of 30 seconds at 94° C., 30 seconds at 55° C., 1 minute at 72° C. The PCR product is purified, digested with NdeI and BamHI and subcloned into pBE3 shuttle vector. This gene library is amplified in E. coli HB101 and transferred into B. subtilis DB428 competent cells for expression and screening, as described elsewhere (35). Thermostability of enzyme variants is determined in the 96-well plate format described previously (33).

This protocol results in the generation of novel sequences containing novel combinations of mutations from the parental sequences as well as novel point mutations. Screening allows the identification of enzyme variants that are more thermostable than the parent enzymes, as in Example 1.

As is apparent from the above examples, primer-based recombination may be used to explore the vast space of potentially useful catalysts for their optimal performance in a wide range of applications as well as to develop or evolve new enzymes for basic structure-function studies.

While the present specification describes using DNA-dependent DNA polymerase and single-stranded DNA as templates, alternative protocols are also feasible for using single-stranded RNA as a template. By using specific protein mRNA as the template and RNA-dependent DNA polymerase (reverse transcriptase) as the catalyst, the methods described herein may be modified to introduce mutations and crossovers into cDNA clones and to create molecular diversity directly from the mRNA level to achieve the goal of optimizing protein functions. This would greatly simplify the ETS (expression-tagged strategy) for novel catalyst discovery.

In addition to the above, the present invention is also useful to probe proteins from obligate intracellular pathogens or other systems where cells of interest cannot be propagated (38).

Having thus described exemplary embodiments of the present invention, it should be noted by those skilled in the art that the within disclosures are exemplary only and that various other alternatives, adaptations, and modifications may be made within the scope of the present invention. Accordingly, the present invention is not limited to the specific embodiments as illustrated herein, but is only limited by the following claims.

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36 22 nucleotides nucleic acid single linear oligonucleotide 1 CCG AGC GTT GCA TAT GTG GAA G 22 21 nucleotides nucleic acid single linear oligonucleotide 2 CGA CTC TAG AGG ATC CGA TTC 21 21 nucleotides nucleic acid single linear oligonucleotide 3 GAG CAC ATC AGA TCT ATT AAC 21 21 nucleotides nucleic acid single linear oligonucleotide 4 GGA GTG GCT CAC AGT CGG TGG 21 21 nucleotides nucleic acid single linear oligonucleotide 5 TTG AAC TAT CGG CTG GGG CGG 21 21 nucleotides nucleic acid single linear oligonucleotide 6 TTA CTA GGG AAG CCG CTG GCA 21 21 nucleotides nucleic acid single linear oligonucleotide 7 TCA GAG ATT ACG ATC GAA AAC 21 21 nucleotides nucleic acid single linear oligonucleotide 8 GGA TTG TAT CGT GTG AGA AAG 21 21 nucleotides nucleic acid single linear oligonucleotide 9 AAT GCC GGA AGC AGC CCC TTC 21 21 nucleotides nucleic acid single linear oligonucleotide 10 CAC GAC AGG AAG ATT TTG ACT 21 20 nucleotides nucleic acid single linear oligonucleotide 11 ACT TAA TCT AGA GGG TAT TA 20 20 nucleotides nucleic acid single linear oligonucleotide 12 AGC CTC GCG GGA TCC CCG GG 20 28 nucleotides nucleic acid single linear oligonucleotide 13 GGT AGA GCG AGT CTC GAG GGG GAG ATG C 28 22 nucleotides nucleic acid single linear oligonucleotide 14 AGC CGG CGT GAC GTG GGT CAG C 22 22 nucleotides nucleic acid single linear oligonucleotide 15 CCG AGC GTT GCA TAT GTG GAA G 22 21 nucleotides nucleic acid single linear oligonucleotide 16 CGA CTC TAG AGG ATC CGA TTC 21 22 nucleotides nucleic acid single linear oligonucleotide 17 CGG TAC GCA TGT AGC CGG TAC G 22 22 nucleotides nucleic acid single linear oligonucleotide 18 CGG TAC GAT TGC CGC CGG TAC G 22 22 nucleotides nucleic acid single linear oligonucleotide 19 CCG AGC GTT GCA TAT GTG GAA G 22 21 nucleotides nucleic acid single linear oligonucleotide 20 CGA CTC TAG AGG ATC CGA TTC 21 18 nucleotides nucleic acid single linear oligonucleotide 21 GGC GGA GCT AGC TTC GTA 18 18 nucleotides nucleic acid single linear oligonucleotide 22 GAT GTG ATG GCT CCT GGC 18 18 nucleotides nucleic acid single linear oligonucleotide 23 CAG AAC ACC GAT TGA GTT 18 18 nucleotides nucleic acid single linear oligonucleotide 24 AGT GCT TTC TAA ACG ATC 18 4 amino acids amino acid linear peptide 25 Ala Ala Pro Phe 4050 nucleotides nucleic acid single linear polynucleotide 26 GGGATCCTCT AAAGTCGACC TGCAGCGTGC CCAGCTGTTC GTGGTGGTGA TCGCGGCCGC 60 GCTGGCCGCC GTCGCGGTCG CCGCCGCCGG GCCGATCGAG TTCGTCGCCT TCGTCGTGCC 120 GCAGATCGCC CTGCGGCTCT GCGGCGGCAG CCGGCCGCCC CTGCTCGCCT CGGCGATGCT 180 CGGCGCGCTG CTGGTGGTCG GCGCCGACCT GGTCGCTCAG ATCGTGGTGG CGCCGAAGGA 240 GCTGCCGGTC GGCCTGCTCA CCGCGATGAT CGGCACCCCG TACCTGCTCT GGCTCCTGCT 300 TCGGCGATCA AGAAAGGTGA GCGGATGAAC GCCCGCCTGC GTGGCGAGGG CCTGCACCTC 360 GCGTACGGGG ACCTGACCGT GATCGACGGC CTCGACGTCG ACGTGCACGA CGGGCTGGTC 420 ACCACCATCA TCGGGCCCAA CGGGTGCGGC AAGTCGACGC TGCTCAAGGC GCTCGGCCGG 480 CTGCTGCGCC CGACCGGCGG GCAGGTGCTG CTGGACGGCC GCCGCATCGA CCGGACCCCC 540 ACCCGTGACG TGGCCCGGGT GCTCGGCGTG CTGCCGCAGT CGCCCACCGC GCCCGAAGGG 600 CTCACCGTCG CCGACCTGGT GATGCGCGGC CGGCACCCGC ACCAGACCTG GTTCCGGCAG 660 TGGTCGCGCG ACGACGAGGA CCAGGTCGCC GACGCGCTGC GCTGGACCGA CATGCTGGCG 720 TACGCGGACC GCCCGGTGGA CGCCCTCTCC GGCGGTCAGC GCCAGCGCGC CTGGATCAGC 780 ATGGCGCTGG CCCAGGGCAC CGACCTGCTG CTGCTGGACG AGCCGACCAC CTTCCTCGAC 840 CTGGCCCACC AGATCGACGT GCTGGACCTG GTCCGCCGGC TGCACGCCGA GATGGGCCGG 900 ACCGTGGTGA TGGTGCTGCA CGACCTGAGC CTGGCCGCCC GGTACGCCGA CCGGCTGATC 960 GCGATGAAGG ACGGCCGGAT CGTGGCGAGC GGGGCGCCGG ACGAGGTGCT CACCCCGGCG 1020 CTGCTGGAGT CGGTCTTCGG GCTGCGCGCG ATGGTGGTGC CCGACCCGGC GACCGGCACC 1080 CCGCTGGTGA TCCCCCTGCC GCGCACCGCC ACCTCGGTGC GGGCCTGAAA TCGATGAGCG 1140 TGGTTGCTTC ATCGGCCTGC CGAGCGATGA GAGTATGTGG GCGGTAGAGC GAGTCCCGAG 1200 GGGGAGATGC CGCCGTGACG TCCTCGTACA TGCGCCTGAA AGCAGCAGCG ATCGCCTTCG 1260 GTGTGATCGT GGCGACCGCA ACCGTGCCGT CACCCGCTTC CGGCAGGGAA CATGACGGCG 1320 GCTATGCGGC CCTGATCCGC CGGGCCTCGT ACGGCGTCCC GCACATCACC GCCGACGACT 1380 TCGGGAGCCT CGGTTTCGGC GTCGGGTACG TGCAGGCCGA GGACAACATC TGCGTCATCG 1440 CCGAGAGCGT GGTGACGGCC AACGGTGAGC GGTCGCGGTG GTTCGGTGCG ACCGGGCCGG 1500 ACGACGCCGA TGTGCGCAGC GACCTCTTCC ACCGCAAGGC GATCGACGAC CGCGTCGCCG 1560 AGCGGCTCCT CGAAGGGCCC CGCGACGGCG TGCGGGCGCC GTCGGACGAC GTCCGGGACC 1620 AGATGCGCGG CTTCGTCGCC GGCTACAACC ACTTCCTACG CCGCACCGGC GTGCACCGCC 1680 TGACCGACCC GGCGTGCCGC GGCAAGGCCT GGGTGCGCCC GCTCTCCGAG ATCGATCTCT 1740 GGCGTACATT GTGGGACAGC ATGGTCCGGG CCGGTTCCGG GGCGCTGCTC GACGGCATCG 1800 TCGCCGCGAC GCCACCGACA GCCGCCGGGC CCGCGTCAGC CCCGGAGGCA CCCGACGCCG 1860 CCGCGATCGC CGCCGCCCTC GACGGGACGA GCGCGGGCAT CGGCAGCAAC GCGTACGGCC 1920 TCGGCGCGCA GGCCACCGTG AACGGCAGCG GGATGGTGCT GGCCAACCCG CACTTCCCGT 1980 GGCAGGGCGC CGCACGCTTC TACCGGATGC ACCTCAAGGT GCCCGGCCGC TACGACGTCG 2040 AGGGCGCGGC GCTGGTCGGC GACCCGATCA TCGAGATCGG GCACAACCGC ACGGTCGCCT 2100 GGAGCCACAC CGTCTCCACC GCCCGCCGGT TCGTGTGGCA CCGCCTGAGC CTCGTGCCCG 2160 GCGACCCCAC CTCCTATTAC GTCGACGGCC GGCCCGAGCG GATGCGCGCC CGCACGGTCA 2220 CGGTCCAGAC CGGCAGCGGC CCGGTCAGCC GCACCTTCCA CGACACCCGC TACGGCCCGG 2280 TGGCCGTGGT GCCGGGCACC TTCGACTGGA CGCCGGCCAC CGCGTACGCC ATCACCGACG 2340 TCAACGCGGG CAACAACCGC GCCTTCGACG GGTGGCTGCG GATGGGCCAG GCCAAGGACG 2400 TCCGGGCGCT CAAGGCGGTC CTCGACCGGC ACCAGTTCCT GCCCTGGGTC AACGTGATCG 2460 CCGCCGACGC GCGGGGCGAG GCCCTCTACG GCGATCATTC GGTCGTCCCC CGGGTGACCG 2520 GCGCGCTCGC TGCCGCCTGC ATCCCGGCGC CGTTCCAGCC GCTCTACGCC TCCAGCGGCC 2580 AGGCGGTCCT GGACGGTTCC CGGTCGGACT GCGCGCTCGG CGCCGACCCC GACGCCGCGG 2640 TCCCGGGCAT TCTCGGCCCG GCGAGCCTGC CGGTGCGGTT CCGCGACGAC TACGTCACCA 2700 ACTCCAACGA CAGTCACTGG CTGGCCAGCC CGGCCGCCCC GCTGGAAGGC TTCCCGCGGA 2760 TCCTCGGCAA CGAACGCACC CCGCGCAGCC TGCGCACCCG GCTCGGGCTG GACCAGATCC 2820 AGCAGCGCCT CGCCGGCACG GACGGTCTGC CCGGCAAGGG CTTCACCACC GCCCGGCTCT 2880 GGCAGGTCAT GTTCGGCAAC CGGATGCACG GCGCCGAACT CGTCCGCGAC GACCTGGTCG 2940 CGCTCTGCCG CCGCCAGCCG ACCGCGACCG CCTCGAACGG CGCGATCGTC GACCTCACCG 3000 CGGCCTGCAC GGCGCTGTCC CGCTTCGATG AGCGTGCCGA CCTGGACAGC CGGGGCGCGC 3060 ACCTGTTCAC CGAGTTCGCC CTCGCGGGCG GAATCAGGTT CGCCGACACC TTCGAGGTGA 3120 CCGATCCGGT ACGCACCCCG CGCCGTCTGA ACACCACGGA TCCGCGGGTA CGGACGGCGC 3180 TCGCCGACGC CGTGCAACGG CTCGCCGGCA TCCCCCTCGA CGCGAAGCTG GGAGACATTC 3240 ACACCGACAG CCGCGGCGAA CGGCGCATCC CCATCCACGG TGGCCGCGGG GAAGCAGGCA 3300 CCTTCAACGT GATCACCAAC CCGCTCGTGC CGGGCGTGGG ATACCCGCAG GTCGTCCACG 3360 GAACATCGTT CGTGATGGCC GTCGAACTCG GCCCGCACGG CCCGTCGGGA CGGCAGATCC 3420 TCACCTATGC GCAGTCGACG AACCCGAACT CACCCTGGTA CGCCGACCAG ACCGTGCTCT 3480 ACTCGCGGAA GGGCTGGGAC ACCATCAAGT ACACCGAGGC GCAGATCGCG GCCGACCCGA 3540 ACCTGCGCGT CTACCGGGTG GCACAGCGGG GACGCTGACC CACGTCACGC CGGCTCGGCC 3600 CGTGCGGGGG CGCAGGGCGC CGATCGTCTC TGCATCGCCG GTCAGCCGGG GCCTGCGTCG 3660 ACCGGCGGCG GCCGGTCGAC GCCCGCGTCC CGGCGCAGCG ACTGGCTGAA GCGCCAGGCG 3720 TCGGCGGCCC GGGGCAGGTT GTTGAACATC ACGTACGCCG GGCCGCCGTC GAGGATGCCG 3780 GCGAGGTGTG CCAGCTCGGC ATCCGTGTAC ACATGCCGGG CGCCGGTGAT GCCGTGCAGC 3840 CGGTAATAGG CCATCGGCGT CAGACTGCGG CGCAGGAACG GGTCGGCGGC GTGGGTCAGG 3900 TCCAGCTCCT GGCACAAGCC CTCGACCACC TCGTCCGGCC ACGGGCCGCG CGGCTCCCAC 3960 AACAGCCGGA CACCGGCCGG CCGGCGCGCT CGGGCGCAGA ACTCACGCAG TCGCGCGATG 4020 GCGGGTTCGG TCGGCCGGAA ACTCGCCGGG 4050 4101 nucleotides nucleic acid single linear polynucleotide 27 AAGCTTGCAT GCCTGCAGCG TGCCCAGCTG TTCGTGGTGG TGATCGCGGC CGCGCTGGCC 60 GCCGTCGCGG TCGCCGCCGC CGGGCCGATC GAGTTCGTCG CCTTCGTCGT GCCGCAGATC 120 GCCCTGCGGC TCTGCGGCGG CAGCCGGCCG CCCCTGCTCG CCTCGGCGAT GCTCGGCGCG 180 CTGCTGGTGG TCGGCGCCGA CCTGGTCGCT CAGATCGTGG TGGCGCCGAA GGAGCTGCCG 240 GTCGGCCTGC TCACCGCGAT GATCGGCACC CCGTACCTGC TCTGGCTCCT GCTTCGGCGA 300 TCAAGAAAGG TGAGCGGATG AACGCCCGCC TGCGTGGCGA GGGCCTGCAC CTCGCGTACG 360 GGGACCTGAC CGTGATCGAC GGCCTCGACG TCGACGTGCA CGACGGGCTG GTCACCACCA 420 TCATCGGGCC CAACGGGTGC GGCAAGTCGA CGCTGCTCAA GGCGCTCGGC CGGCTGCTGC 480 GCCCGACCGG CGGGCAGGTG CTGCTGGACG GCCGCCGCAT CGACCGGACC CCCACCCGTG 540 ACGTGGCCCG GGTGCTCGGC GTGCTGCCGC AGTCGCCCAC CGCGCCCGAA GGGCTCACCG 600 TCGCCGACCT GGTGATGCGC GGCCGGCACC CGCACCAGAC CTGGTTCCGG CAGTGGTCGC 660 GCGACGACGA GGACCAGGTC GCCGACGCGC TGCGCTGGAC CGACATGCTG GCGTACGCGG 720 ACCGCCCGGT GGACGCCCTC TCCGGCGGTC AGCGCCAGCG CGCCTGGATC AGCATGGCGC 780 TGGCCCAGGG CACCGACCTG CTGCTGCTGG ACGAGCCGAC CACCTTCCTC GACCTGGCCC 840 ACCAGATCGA CGTGCTGGAC CTGGTCCGCC GGCTGCACGC CGAGATGGGC CGGACCGTGG 900 TGATGGTGCT GCACGACCTG AGCCTGGCCG CCCGGTACGC CGACCGGCTG ATCGCGATGA 960 AGGACGGCCG GATCGTGGCG AGCGGGGCGC CGGACGAGGT GCTCACCCCG GCGCTGCTGT 1020 AGTCGGTCTT CGGGCTGCGC GCGATGGTGG TGCCCGACCC GGCGACCGGC ACCCCGCTGG 1080 TGATCCCCCT GCCGCGCACC GCCACCTCGG TGCGGGCCTG AAATCGATGA GCGTGGTTGC 1140 TTCATCGGCC TGCCGAGCGA TGAGAGTATG TGGGCGGTAG AGCGAGTCTC GAGGGGGAGA 1200 TGCCGCCGTG ACGTCCTCGT ACATGCGCCT GAAAGCAGCA GCGATCGCCT TCGGTGTGAT 1260 CGTGGCGACC GCAGCCGTGC CGTCACCCGC TTCCGGCAGG GAACATGACG GCGGCTATGC 1320 GGCCCTGATC CGCCGGGCCT CGTACGGCGT CCCGCACATC ACCGCCGACG ACTTCGGGAG 1380 CCTCGGTTTC GGCGTCGGGT ACGTGCAGGC CGAGGACAAC ATCTGCGTCA TCGCCGAGAG 1440 CGTGGTAACG GCCAACGGTG AGCGGTCGCG GTGGTTCGGT GCGACCGGGC CGGACGACGC 1500 CGATGTGCGC AGCGACCTCT TCCACCGCAA GGCGATCGAC GACCGCGTCG CCGAGCGGCT 1560 CCTCGAAGGG CCCCGCGACG GCGTGCGGGC GCCGTCGGAC GACGTCCGGG ACCAGATGCG 1620 CGGCTTCGTC GCCGGCTACA ACCACTTCCT ACGCCGCACC GGCGTGCACC GCCTGACCGA 1680 CCCGGCGTGC CGCGGCAAGG CCTGGGTGCG CCCGCTCTCC GAGATCGATC TCTGGCGTAC 1740 GTCGTGGGAC AGCATGGTCC GGGCCGGTTC CGGGGCGCTG CTCGACGGCA TCGTCGCCGC 1800 GACGCCACCT ACAGCCGCCG GGCCCGCGTC AGCCCCGGAG GCACCCGACG CCGCCGCGAT 1860 CGCCGCCGCC CTCGACGGGA CGAGCGCGGG CATCGGCAGC AACGCGTACG GCCTCGGCGC 1920 GCAGGCCACC GTGAACGGCA GCGGGATGGT GCTGGCCAAC CCGCACTTCC CGTGGCAGGG 1980 CGCCGAACGC TTCTACCGGA TGCACCTCAA GGTGCCCGGC CGCTACGACG TCGAGGGCGC 2040 GGCGCTGATC GGCGACCCGA TCATCGGGAT CGGGCACAAC CGCACGGTCG CCTGGAGCCA 2100 CACCGTCTCC ACCGCCCGCC GGTTCGTGTG GCACCGCCTG AGCCTCGTGC CCGGCGACCC 2160 CACCTCCTAT TACGTCGACG GCCGGCCCGA GCGGATGCGC GCCCGCACGG TCACGGTCCA 2220 GACCGGCAGC GGCCCGGTCA GCCGCACCTT CCACGACACC CGCTACGGCC CGGTGGCCGT 2280 GATGCCGGGC ACCTTCGACT GGACGCCGGC CACCGCGTAC GCCATCACCG ACGTCAACGC 2340 GGGCAACAAC CGCGCCTTCG ACGGGTGGCT GCGGATGGGC CAGGCCAAGG ACGTCCGGGC 2400 GCTCAAGGCG GTCCTCGACC GGCACCAGTT CCTGCCCTGG GTCAACGTGA TCGCCGCCGA 2460 CGCGCGGGGC GAGGCCCTCT ACGGCGATCA TTCGGTCGTC CCCCGGGTGA CCGGCGCGCT 2520 CGCTGCCGCC TGCATCCCGG CGCCGTTCCA GCCGCTCTAC GCCTCCAGCG GCCAGGCGGT 2580 CCTGGACGGT TCCCGGTCGG ACTGCGCGCT CGGCGCCGAC CCCGACGCCG CGGTCCCGGG 2640 CATTCTCGGC CCGGCGAGCC TGCCGGTGCG GTTCCGCGAC GACTACGTCA CCAACTCCAA 2700 CGACAGTCAC TGGCTGGCCA GCCCGGCCGC CCCGCTGGAA GGCTTCCCGC GGATCCTCGG 2760 CAACGAACGC ACCCCGCGCA GCCTGCGCAC CCGGCTCGGG CTGGACCAGA TCCAGCAGCG 2820 CCTCGCCGGC ACGGACGGTC TGCCCGGCAA GGGCTTCACC ACCGCCCGGC TCTGGCAGGT 2880 CATGTTCGGC AACCGGATGC ACGGCGCCGA ACTCGCCCGC GACGACCTGG TCGCGCTCTG 2940 CCGCCGCCAG CCGACCGCGA CCGCCTCGAA CGGCGCGATC GTCGACCTCA CCGCGGCCTG 3000 CACGGCGCTG TCCCGCTTCG ATGAGCGTGC CGACCTGGAC AGCCGGGGCG CGCACCTGTT 3060 CACCGAGTTC GCCCTCGCGG GCGGAATCAG GTTCGCCGAC ACCTTCGAGG TGACCGATCC 3120 GGTACGCACC CCGCGCCGTC TGAACACCAC GGATCCGCGG GTACGGACGG CGCTCGCCGA 3180 CGCCGTGCAA CGGCTCGCCG GCATCCCCCT CGACGCGAAG CTGGGAGACA TCCACACCGA 3240 CAGCCGCGGC GAACGGCGCA TCCCCATCCA CGGTGGCCGC GGGGAAGCAG GCACCTTCAA 3300 CGTGATCACC AACCCGCTCG TGCCGGGCGT GGGATACCCG CAGGTCGTCC ACGGAACATC 3360 GTTCGTGATG GCCGTCGAAC TCGGCCCGCA CGGCCCGTCG GGACGGCAGA TCCTCACCTA 3420 TGCGCAGTCG ACGAACCCGA ACTCACCCTG GTACGCCGAC CAGACCGTGC TCTACTCGCG 3480 GAAGGGCTGG GACACCATCA AGTACACCGA GGCGCAGATC GCGGCCGACC CGAACCTGCG 3540 CGTCTACCGG GTGGCACAGC GGGGACGCTG ACCCACGTCA CGCCGGCTCG GCCCGTGCGG 3600 GGGCGCAGGG CGCCGATCGT CTCTGCATCG CCGGTCAGCC GGGGCCTGCG TCGACCGGCG 3660 GCGGCCGGTC GACGCCCGCG TCCCGGCGCA GCGACTGGCT GAAGCGCCAG GCGTCGGCGG 3720 CCCGGGGCAG GTTGTTGAAC ATCACGTACG CCGGGCCGCC GTCGAGGATG CCGGCGAGGT 3780 GTGCCAGCTC GGCATCCGTA TACACATGCC GGGCGCCGGT GATGCCGTGC AGCCGGTAAT 3840 AGGCCATCGG CGTCAGACTG CGGCGCAGGA ACGGGTCGGC GGCGTGGGTC AGGTCCAGCT 3900 CCTGGCACAA GCCCTCGACC ACCTCGTCCG GCCACGGGCC GCGCGGCTCC CACAACAGCC 3960 GGACACCGGC CGGCCGGCGC GCTCGGGCGC AGAACTCACG CAGTCGCGCG ATGGCGGGTT 4020 CGGTCGGCCG GAAACTCGCC GGGCACTGCA GGTCGACTCT AGAGGATCCC CGGGTACCGA 4080 GCTCGAATTC GTAATCATGT C 4101 4093 nucleotides nucleic acid single linear polynucleotide 28 AAGCTTGCAT GCCTGCAGCG TGCCCAGCTG TTCGTGGTGG TGATCGCGGC CGCGCTGGCC 60 GCCGTCGCGG TCGCCGCCGC CGGGCCGATC GAGTTCGTCG CCTTCGTCGT GCCGCAGATC 120 GCCCTGCGGC TCTGCGGCGG CAGCCGGCCG CCCCTGCTCG CCTCGGCGAT GCTCGGCGCG 180 CTGCTGGTGG TCGGCGCCGA CCTGGTCGCT CAGATCGTGG TGGCGCCGAA GGAGCTGCCG 240 GTCGGCCTGC TCACCGCGAT GATCGGCACC CCGTACCTGC TCTGGCTCCT GCTTCGGCGA 300 TCAAGAAAGG TGAGCGGATG AACGCCCGCC TGCGTGGCGA GGGCCTGCAC CTCGCGTACG 360 GGGACCTGAC CGTGATCGAC GGCCTCGACG TCGACGTGCA CGACGGGCTG GTCACCACCA 420 TCATCGGGCC CAACGGGTGC GGCAAGTCGA CGCTGCTCAA GGCGCTCGGC CGGCTGCTGC 480 GCCCGACCGG CGGGCAGGTG CTGCTGGACG GCCGCCGCAT CGACCGGACC CCCACCCGTG 540 ACGTGGCCCG GGTGCTCGGC GTGCTGCCGC AGTCGCCCAC CGCGCCCGAA GGGCTCACCG 600 TCGCCGACCT GGTGATGCGC GGCCGGCACC CGCACCAGAC CTGGTTCCGG CAGTGGTCGC 660 GCGACGACGA GGACCAGGTC GCCGACGCGC TGCGCTGGAC CGACATGCTG GCGTACGCGG 720 ACCGCCCGGT GGACGCCCTC TCCGGCGGTC AGCGCCAGCG CGCCTGGATC AGCATGGCGC 780 TGGCCCAGGG CACCGACCTG CTGCTGCTGG ACGAGCCGAC CACCTTCCTC GACCTGGCCC 840 ACCAGATCGA CGTGCTGGAC CTGGTCCGCC GGCTGCACGC CGAGATGGGC CGGACCGTGG 900 TGATGGTGCT GCACGACCTG AGCCTGGCCG CCCGGTACGC CGACCGGCTG ATCGCGATGA 960 AGGACGGCCG GATCGTGGCG AGCGGGGCGC CGGACGAGGT GCTCACCCCG GCGCTGCTGG 1020 AGTCGGTCTT CGGGCTGCGC GCGATGGTGG TGCCCGACCC GGCGACCGGC ACCCCGCTGG 1080 TGATCCCCCT GCCGCGCACC GCCACCTCGG TGCGGGCCTG AAATCGATGA GCGTGGTTGC 1140 TTCATCGGCC TGCCGAGCGA TGAGAGTATG TGGGCGGTAG AGCGAGTCCC GAGGGGGAGA 1200 TGCCGCCGTG ACGTCCTCGT ACATGCGCCT GAAAGCAGCA GCGATCGCCT TCGGTGTGAT 1260 CGTGGCGACC GCAACCGTGC CGTCACCCGC TTCCGGCAGG GAACATGACG GCGGCTATGC 1320 GGCCCTGATC CGCCGGGCCT CGTACGGCGT CCCGCACATC ACCGCCGACG ACTTCGGGAG 1380 CCTCGGTTTC GGCGTCGGGT ACGTGCAGGC CGAGGACAAC ATCTGCGTCA TCGCCGAGAG 1440 CGTGGTGACG GCCAACGGTG AGCGGTCGCG GTGGTTCGGT GCGACCGGGC CGGACGACGC 1500 CGATGTGCGC AGCGACCTCT TCCACCGCAA GGCGATCGAC GACCGCGTCG CCGAGCGGCT 1560 CCTCGAAGGG CCCCGCGACG GCGTGCGGGC GCCGTCGGAC GACGTCCGGG ACCAGATGCG 1620 CGGCTTCGTC GCCGGCTACA ACCACTTCCT ACGCCGCACC GGCGTGCACC GCCTGACCGA 1680 CCCGGCGTGC CGCGGCAAGG CCTGGGTGCG CCCGCTCTCC GAGATCGATC TCTGGCGTAC 1740 ATTGTGGGAC AGCATGGTCC GGGCCGGTTC CGGGGCGCTG CTCGACGGCA TCGTCGCCGC 1800 GACGCCACCG ACAGCCGCCG GGCCCGCGTC AGCCCCGGAG GCACCCGACG CCGCCGCGAT 1860 CGCCGCCGCC CTCGACGGGA CGAGCGCGGG CATCGGCAGC AACGCGTACG GCCTCGGCGC 1920 GCAGGCCACC GTGAACGGCA GCGGGATGGT GCTGGCCAAC CCGCACTTCC CGTGGCAGGG 1980 CGCCGCACGC TTCTACCGGA TGCACCTCAA GGTGCCCGGC CGCTACGACG TCGAGGGCGC 2040 GGCGCTGGTC GGCGACCCGA TCATCGAGAT CGGGCACAAC CGCACGGTCG CCTGGAGCCA 2100 CACCGTCTCC ACCGCCCGCC GGTTCGTGTG GCACCGCCTG AGCCTCGTGC CCGGCGACCC 2160 CACCTCCTAT TACGTCGACG GCCGGCCCGA GCGGATGCGC GCCCGCACGG TCACGGTCCA 2220 GACCGGCAGC GGCCCGGTCA GCCGCACCTT CCACGACACC CGCTACGGCC CGGTGGCCGT 2280 GGTGCCGGGC ACCTTCGACT GGACGCCGGC CACCGCGTAC GCCATCACCG ACGTCAACGC 2340 GGGCAACAAC CGCGCCTTCG ACGGGTGGCT GCGGATGGGC CAGGCCAAGG ACGTCCGGGC 2400 GCTCAAGGCG GTCCTCGACC GGCACCAGTT CCTGCCCTGG GTCAACGTGA TCGCCGCCGA 2460 CGCGCGGGGC GAGGCCCTCT ACGGCGATCA TTCGGTCGTC CCCCGGGTGA CCGGCGCGCT 2520 CGCTGCCGCC TGCATCCCGG CGCCGTTCCA GCCGCTCTAC GCCTCCAGCG GCCAGGCGGT 2580 CCTGGACGGT TCCCGGTCGG ACTGCGCGCT CGGCGCCGAC CCCGACGCCG CGGTCCCGGG 2640 CATTCTCGGC CCGGCGAGCC TGCCGGTGCG GTTCCGCGAC GACTACGTCA CCAACTCCAA 2700 CGACAGTCAC TGGCTGGCCA GCCCGGCCGC CCCGCTGGAA GGCTTCCCGC GGATCCTCGG 2760 CAACGAACGC ACCCCGCGCA GCCTGCGCAC CCGGCTCGGG CTGGACCAGA TCCAGCAGCG 2820 CCTCGCCGGC ACGGACGGTC TGCCCGGCAA GGGCTTCACC ACCGCCCGGC TCTGGCAGGT 2880 CATGTTCGGC AACCGGATGC ACGGCGCCGA ACTCGTCCGC GACGACCTGG TCGCGCTCTG 2940 CCGCCGCCAG CCGACCGCGA CCGCCTCGAA CGGCGCGATC GTCGACCTCA CCGCGGCCTG 3000 CACGGCGCTG TCCCGCTTCG ATGAGCGTGC CGACCTGGAC AGCCGGGGCG CGCACCTGTT 3060 CACCGAGTTC GCCCTCGCGG GCGGAATCAG GTTCGCCGAC ACCTTCGAGG TGACCGATCC 3120 GGTACGCACC CCGCGCCGTC TGAACACCAC GGATCCGCGG GTACGGACGG CGCTCGCCGA 3180 CGCCGTGCAA CGGCTCGCCG GCATCCCCCT CGACGCGAAG CTGGGAGACA TTCACACCGA 3240 CAGCCGCGGC GAACGGCGCA TCCCCATCCA CGGTGGCCGC GGGGAAGCAG GCACCTTCAA 3300 CGTGATCACC AACCCGCTCG TGCCGGGCGT GGGATACCCG CAGGTCGTCC ACGGAACATC 3360 GTTCGTGATG GCCGTCGAAC TCGGCCCGCA CGGCCCGTCG GGACGGCAGA TCCTCACCTA 3420 TGCGCAGTCG ACGAACCCGA ACTCACCCTG GTACGCCGAC CAGACCGTGC TCTACTCGCG 3480 GAAGGGCTGG GACACCATCA AGTACACCGA GGCGCAGATC GCGGCCGACC CGAACCTGCG 3540 CGTCTACCGG GTGGCACAGC GGGGACGCTG ACCCACGTCA CGCCGGCTCG GCCCGTGCGG 3600 GGGCGCAGGG CGCCGATCGT CTCTGCATCG CCGGTCAGCC GGGGCCTGCG TCGACCGGCG 3660 GCGGCCGGTC GACGCCCGCG TCCCGGCGCA GCGACTGGCT GAAGCGCCAG GCGTCGGCGG 3720 CCCGGGGCAG GTTGTTGAAC ATCACGTACG CCGGGCCGCC GTCGAGGATG CCGGCGAGGT 3780 GTGCCAGCTC GGCATCCGTG TACACATGCC GGGCGCCGGT GATGCCGTGC AGCCGGTAAT 3840 AGGCCATCGG CGTCAGACTG CGGCGCAGGA ACGGGTCGGC GGCGTGGGTC AGGTCCAGCT 3900 CCTGGCACAA GCCCTCGACC ACCTCGTCCG GCCACGGGCC GCGCGGCTCC CACAACAGCC 3960 GGACACCGGC CGGCCGGCGC GCTCGGGCGC AGAACTCACG CAGTCGCGCG ATGGCGGGTT 4020 CGGTCGGCCG GAAACTCGCC GGGCACTGCA GGTCGACTCT AGAGGATCCC CCGGGTACCG 4080 AGCTCGAATT CGT 4093 3222 nucleotides nucleic acid single linear polynucleotide 29 GCCGGCTGCA CGCCGAGATG GGCCGGACCG TGGTGATGGT GCTGCACGAC CTGAGCCTGG 60 CCGCCCGGTA CGCCGACCGG CTGATCGCGA TGAAGGACGG CCGGATCGTG GCGAGCGGGG 120 CGCCGGACGA GGTGCTCACC CCGGCGCTGC TGGAGTCGGT CTTCGGGCTG CGCGCGATGG 180 TGGTGCCCGA CCCGGCGACC GGCACCCCGC TGGTGATCCC CCTGCCGCGC ACCGCCACCT 240 CGGTGCGGGC CTGAAATCGA TGAGCGTGGT TGCTTCATCG GCCTGCCGAG CGATGAGAGT 300 ATGTGGGCGG TAGAGCGAGT CCCGAGGGGG AGATGCCGCC GTGACGTCCT CGTACATGCG 360 CCTGAAAGCA GCAGCGATCG CCTTCGGTGT GATCGTGGCG ACCGCAACCG TGCCGTCACC 420 CGCTTCCGGC AGGGAACATG ACGGCGGCTA TGCGGCCCTG ATCCGCCGGG CCTCGTACGG 480 CGTCCCGCAC ATCACCGCCG ACGACTTCGG GAGCCTCGGT TTCGGCGTCG GGTACGTGCA 540 GGCCGAGGAC AACATCTGCG TCATCGCCGA GAGCGTGGTG ACGGCCAACG GTGAGCGGTC 600 GCGGTGGTTC GGTGCGACCG GGCCGGACGA CGCCGATGTG CGCAGCGACC TCTTCCACCG 660 CAAGGCGATC GACGACCGCG TCGCCGAGCG GCTCCTCGAA GGGCCCCGCG ACGGCGTGCG 720 GGCGCCGTCG GACGACGTCC GGGACCAGAT GCGCGGCTTC GTCGCCGGCT ACAACCACTT 780 CCTACGCCGC ACCGGCGTGC ACCGCCTGAC CGACCCGGCG TGCCGCGGCA AGGCCTGGGT 840 GCGCCCGCTC TCCGAGATCG ATCTCTGGCG TACATTGTGG GACAGCATGG TCCGGGCCGG 900 TTCCGGGGCG CTGCTCGACG GCATCGTCGC CGCGACGCCA CCGACAGCCG CCGGGCCCGC 960 GTCAGCCCCG GAGGCACCCG ACGCCGCCGC GATCGCCGCC GCCCTCGACG GGACGAGCGC 1020 GGGCATCGGC AGCAACGCGT ACGGCCTCGG CGCGCAGGCC ACCGTGAACG GCAGCGGGAT 1080 GGTGCTGGCC AACCCGCACT TCCCGTGGCA GGGCGCCGCA CGCTTCTACC GGATGCACCT 1140 CAAGGTGCCC GGCCGCTACG ACGTCGAGGG CGCGGCGCTG GTCGGCGACC CGATCATCGA 1200 GATCGGGCAC AACCGCACGG TCGCCTGGAG CCACACCGTC TCCACCGCCC GCCGGTTCGT 1260 GTGGCACCGC CTGAGCCTCG TGCCCGGCGA CCCCACCTCC TATTACGTCG ACGGCCGGCC 1320 CGAGCGGATG CGCGCCCGCA CGGTCACGGT CCAGACCGGC AGCGGCCCGG TCAGCCGCAC 1380 CTTCCACGAC ACCCGCTACG GCCCGGTGGC CGTGATGCCG GGCACCTTCG ACTGGACGCC 1440 GGCCACCGCG TACGCCATCA CCGACGTCAA CGCGGGCAAC AACCGCGCCT TCGACGGGTG 1500 GCTGCGGATG GGCCAGGCCA AGGACGTCCG GGCGCTCAAG GCGGTCCTCG ACCGGCACCA 1560 GTTCCTGCCC TGGGTCAACG TGATCGCCGC CGACGCGCGG GGCGAGGCCC TCTACGGCGA 1620 TCATTCGGTC GTCCCCCGGG TGACCGGCGC GCTCGCTGCC GCCTGCATCC CGGCGCCGTT 1680 CCAGCCGCTC TACGCCTCCA GCGGCCAGGC GGTCCTGGAC GGTTCCCGGT CGGACTGCGC 1740 GCTCGGCGCC GACCCCGACG CCGCGGTCCC GGGCATTCTC GGCCCGGCGA GCCTGCCGGT 1800 GCGGTTCCGC GACGACTACG TCACCAACTC CAACGACAGT CACTGGCTGG CCAGCCCGGC 1860 CGCCCCGCTG GAAGGCTTCC CGCGGATCCT CGGCAACGAA CGCACCCCGC GCAGCCTGCG 1920 CACCCGGCTC GGGCTGGACC AGATCCAGCA GCGCCTCGCC GGCACGGACG GTCTGCCCGG 1980 CAAGGGCTTC ACCACCGCCC GGCTCTGGCA GGTCATGTTC GGCAACCGGA TGCACGGCGC 2040 CGAACTCGCC CGCGACGACC TGGTCGCGCT CTGCCGCCGC CAGCCGACCG CGACCGCCTC 2100 GAACGGCGCG ATCGTCGACC TCACCGCGGC CTGCACGGCG CTGTCCCGCT TCGATGAGCG 2160 TGCCGACCTG GACAGCCGGG GCGCGCACCT GTTCACCGAG TTCGCCCTCG CGGGCGGAAT 2220 CAGGTTCGCC GACACCTTCG AGGTGACCGA TCCGGTACGC ACCCCGCGCC GTCTGAACAC 2280 CACGGATCCG CGGGTACGGA CGGCGCTCGC CGACGCCGTG CAACGGCTCG CCGGCATCCC 2340 CCTCGACGCG AAGCTGGGAG ACATCCACAC CGACAGCCGC GGCGAACGGC GCATCCCCAT 2400 CCACGGTGGC CGCGGGGAAG CAGGCACCTT CAACGTGATC ACCAACCCGC TCGTGCCGGG 2460 CGTGGGATAC CCGCAGGTCG TCCACGGAAC ATCGTTCGTG ATGGCCGTCG AACTCGGCCC 2520 GCACGGCCCG TCGGGACGGC AGATCCTCAC CTATGCGCAG TCGACGAACC CGAACTCACC 2580 CTGGTACGCC GACCAGACCG TGCTCTACTC GCGGAAGGGC TGGGACACCA TCAAGTACAC 2640 CGAGGCGCAG ATCGCGGCCG ACCCGAACCT GCGCGTCTAC CGGGTGGCAC AGCGGGGACG 2700 CTGACCCACG TCACGCCGGC TCGGCCCGTG CGGGGGCGCA GGGCGCCGAT CGTCTCTGCA 2760 TCGCCGGTCA GCCGGGGCCT GCGTCGACCG GCGGCGGCCG GTCGACGCCC GCGTCCCGGC 2820 GCAGCGACTG GCTGAAGCGC CAGGCGTCGG CGGCCCGGGG CAGGTTGTTG AACATCACGT 2880 ACGCCGGGCC GCCGTCGAGG ATGCCGGCGA GGTGTGCCAG CTCGGCATCC GTATACACAT 2940 GCCGGGCGCC GGTGATGCCG TGCAGCCGGT AATAGGCCAT CGGCGTCAGA CTGCGGCGCA 3000 GGAACGGGTC GGCGGCGTGG GTCAGGTCCA GCTCCTGGCA CAAGCCCTCG ACCACCTCGT 3060 CCGGCCACGG GCCGCGCGGC TCCCACAACA GCCGGACACC GGCCGGCCGG CGCGCTCGGG 3120 CGCAGAACTC ACGCAGTCGC GCGATGGCGG GTTCGGTCGG CCGGAAACTC GCCGGGCACT 3180 GCAGGTCGAC TCTAGAGGAT CCCCGGGTAC CGAGCTCGAA TT 3222 3193 nucleotides nucleic acid single linear polynucleotide 30 GATGGTGCTG CACGACCTGA GCCTGGCCGC CCGGTACGCC GACCGGCTGA TCGCGATGAA 60 GGACGGCCGG ATCGTGGCGA GCGGGGCGCC GGACGAGGTG CTCACCCCGG CGCTGCTGTA 120 GTCGGTCTTC GGGCTGCGCG CGATGGTGGT GCCCGACCCG GCGACCGGCA CCCCGCTGGT 180 GATCCCCCTG CCGCGCACCG CCACCTCGGT GCGGGCCTGA AATCGATGAG CGTGGTTGCT 240 TCATCGGCCT GCCGAGCGAT GAGAGTATGT GGGCGGTAGA GCGAGTCTCG AGGGGGAGAT 300 GCCGCCGTGA CGTCCTCGTA CATGCGCCTG AAAGCAGCAG CGATCGCCTT CGGTGTGATC 360 GTGGCGACCG CAGCCGTGCC GTCACCCGCT TCCGGCAGGG AACATGACGG CGGCTATGCG 420 GCCCTGATCC GCCGGGCCTC GTACGGCGTC CCGCACATCA CCGCCGACGA CTTCGGGAGC 480 CTCGGTTTCG GCGTCGGGTA CGTGCAGGCC GAGGACAACA TCTGCGTCAT CGCCGAGAGC 540 GTGGTAACGG CCAACGGTGA GCGGTCGCGG TGGTTCGGTG CGACCGGGCC GGACGACGCC 600 GATGTGCGCA GCGACCTCTT CCACCGCAAG GCGATCGACG ACCGCGTCGC CGAGCGGCTC 660 CTCGAAGGGC CCCGCGACGG CGTGCGGGCG CCGTCGGACG ACGTCCGGGA CCAGATGCGC 720 GGCTTCGTCG CCGGCTACAA CCACTTCCTA CGCCGCACCG GCGTGCACCG CCTGACCGAC 780 CCGGCGTGCC GCGGCAAGGC CTGGGTGCGC CCGCTCTCCG AGATCGATCT CTGGCGTACG 840 TCGTGGGACA GCATGGTCCG GGCCGGTTCC GGGGCGCTGC TCGACGGCAT CGTCGCCGCG 900 ACGCCACCTA CAGCCGCCGG GCCCGCGTCA GCCCCGGAGG CACCCGACGC CGCCGCGATC 960 GCCGCCGCCC TCGACGGGAC GAGCGCGGGC ATCGGCAGCA ACGCGTACGG CCTCGGCGCG 1020 CAGGCCACCG TGAACGGCAG CGGGATGGTG CTGGCCAACC CGCACTTCCC GTGGCAGGGC 1080 GCCGAACGCT TCTACCGGAT GCACCTCAAG GTGCCCGGCC GCTACGACGT CGAGGGCGCG 1140 GCGCTGATCG GCGACCCGAT CATCGGGATC GGGCACAACC GCACGGTCGC CTGGAGCCAC 1200 ACCGTCTCCA CCGCCCGCCG GTTCGTGTGG CACCGCCTGA GCCTCGTGCC CGGCGACCCC 1260 ACCTCCTATT ACGTCGACGG CCGGCCCGAG CGGATGCGCG CCCGCACGGT CACGGTCCAG 1320 ACCGGCAGCG GCCCGGTCAG CCGCACCTTC CACGACACCC GCTACGGCCC GGTGGCCGTG 1380 ATGCCGGGCA CCTTCGACTG GACGCCGGCC ACCGCGTACG CCATCACCGA CGTCAACGCG 1440 GGCAACAACC GCGCCTTCGA CGGGTGGCTG CGGATGGGCC AGGCCAAGGA CGTCCGGGCG 1500 CTCAAGGCGG TCCTCGACCG GCACCAGTTC CTGCCCTGGG TCAACGTGAT CGCCGCCGAC 1560 GCGCGGGGCG AGGCCCTCTA CGGCGATCAT TCGGTCGTCC CCCGGGTGAC CGGCGCGCTC 1620 GCTGCCGCCT GCATCCCGGC GCCGTTCCAG CCGCTCTACG CCTCCAGCGG CCAGGCGGTC 1680 CTGGACGGTT CCCGGTCGGA CTGCGCGCTC GGCGCCGACC CCGACGCCGC GGTCCCGGGC 1740 ATTCTCGGCC CGGCGAGCCT GCCGGTGCGG TTCCGCGACG ACTACGTCAC CAACTCCAAC 1800 GACAGTCACT GGCTGGCCAG CCCGGCCGCC CCGCTGGAAG GCTTCCCGCG GATCCTCGGC 1860 AACGAACGCA CCCCGCGCAG CCTGCGCACC CGGCTCGGGC TGGACCAGAT CCAGCAGCGC 1920 CTCGCCGGCA CGGACGGTCT GCCCGGCAAG GGCTTCACCA CCGCCCGGCT CTGGCAGGTC 1980 ATGTTCGGCA ACCGGATGCA CGGCGCCGAA CTCGCCCGCG ACGACCTGGT CGCGCTCTGC 2040 CGCCGCCAGC CGACCGCGAC CGCCTCGAAC GGCGCGATCG TCGACCTCAC CGCGGCCTGC 2100 ACGGCGCTGT CCCGCTTCGA TGAGCGTGCC GACCTGGACA GCCGGGGCGC GCACCTGTTC 2160 ACCGAGTTCG CCCTCGCGGG CGGAATCAGG TTCGCCGACA CCTTCGAGGT GACCGATCCG 2220 GTACGCACCC CGCGCCGTCT GAACACCACG GATCCGCGGG TACGGACGGC GCTCGCCGAC 2280 GCCGTGCAAC GGCTCGCCGG CATCCCCCTC GACGCGAAGC TGGGAGACAT CCACACCGAC 2340 AGCCGCGGCG AACGGCGCAT CCCCATCCAC GGTGGCCGCG GGGAAGCAGG CACCTTCAAC 2400 GTGATCACCA ACCCGCTCGT GCCGGGCGTG GGATACCCGC AGGTCGTCCA CGGAACATCG 2460 TTCGTGATGG CCGTCGAACT CGGCCCGCAC GGCCCGTCGG GACGGCAGAT CCTCACCTAT 2520 GCGCAGTCGA CGAACCCGAA CTCACCCTGG TACGCCGACC AGACCGTGCT CTACTCGCGG 2580 AAGGGCTGGG ACACCATCAA GTACACCGAG GCGCAGATCG CGGCCGACCC GAACCTGCGC 2640 GTCTACCGGG TGGCACAGCG GGGACGCTGA CCCACGTCAC GCCGGCTCGG CCCGTGCGGG 2700 GGCGCAGGGC GCCGATCGTC TCTGCATCGC CGGTCAGCCG GGGCCTGCGT CGACCGGCGG 2760 CGGCCGGTCG ACGCCCGCGT CCCGGCGCAG CGACTGGCTG AAGCGCCAGG CGTCGGCGGC 2820 CCGGGGCAGG TTGTTGAACA TCACGTACGC CGGGCCGCCG TCGAGGATGC CGGCGAGGTG 2880 TGCCAGCTCG GCATCCGTAT ACACATGCCG GGCGCCGGTG ATGCCGTGCA GCCGGTAATA 2940 GGCCATCGGC GTCAGACTGC GGCGCAGGAA CGGGTCGGCG GCGTGGGTCA GGTCCAGCTC 3000 CTGGCACAAG CCCTCGACCA CCTCGTCCGG CCACGGGCCG CGCGGCTCCC ACAACAGCCG 3060 GACACCGGCC GGCCGGCGCG CTCGGGCGCA GAACTCACGC AGTCGCGCGA TGGCGGGTTC 3120 GGTCGGCCGG AAACTCGCCG GGCACTGCAG GTCGACTCTA GAGGATCCCC GGGTACCGAG 3180 CTCGAATTCG TTA 3193 2929 nucleotides nucleic acid single linear polynucleotide 31 ATCGATGAGC GTGGTTGCTT CATCGGCCTG CCGAGCGATG AGAGTATGTG GGCGGTAGAG 60 CGAGTCTCGA GGGGGAGATG CCGCCGTGAC GTCCTCGTAC ATGCGCCTGA AAGCAGCAGC 120 GATCGCCTTC GGTGTGATCG TGGCGACCGC AGCCGTGCCG TCACCCGCTT CCGGCAGGGA 180 ACATGACGGC GGCTATGCGG CCCTGATCCG CCGGGCCTCG TACGGCGTCC CGCACATCAC 240 CGCCGACGAC TTCGGGAGCC TCGGTTTCGG CGTCGGGTAC GTGCAGGCCG AGGACAACAT 300 CTGCGTCATC GCCGAGAGCG TGGTGACGGC CAACGGTGAG CGGTCGCGGT GGTTCGGTGC 360 GACCGGGCCG GACGACGCCG ATGTGCGCAG CGACCTCTTC CACCGCAAGG CGATCGACGA 420 CCGCGTCGCC GAGCGGCTCC TCGAAGGGCC CCGCGACGGC GTGCGGGCGC CGTCGGACGA 480 CGTCCGGGAC CAGATGCGCG GCTTCGTCGC CGGCTACAAC CACTTCCTAC GCCGCACCGG 540 CGTGCACCGC CTGACCGACC CGGCGTGCCG CGGCAAGGCC TGGGTGCGCC CGCTCTCCGA 600 GATCGATCTC TGGCGTACGT CGTGGGACAG CATGGTCCGG GCCGGTTCCG GGGCGCTGCT 660 CGACGGCATC GTCGCCGCGA CGCCACCGAC AGCCGCCGGG CCCGCGTCAG CCCCGGAGGC 720 ACCCGACGCC GCCGCGATCG CCGCCGCCCT CGACGGGACG AGCGCGGGCA TCGGCAGCAA 780 CGCGTACGGC CTCGGCGCGC AGGCCACCGT GAACGGCAGC GGGATGGTGC TGGCCAACCC 840 GCACTTCCCG TGGCAGGGCG CCGAACGCTT CTACCGGATG CACCTCAAGG TGCCCGGCCG 900 CTACGACGTC GAGGGCGCGG CGCTGATCGG CGACCCGATC ATCGAGATCG GGCACAACCG 960 CACGGTCGCC TGGAGCCACA CCGTCTCCAC CGCCCGCCGG TTCGTGTGGC ACCGCCTGAG 1020 CCTCGTGCCC GGCGACCCCA CCTCCTATTA CGTCGACGGC CGGCCCGAGC GGATGCGCGC 1080 CCGCACGGTC ACGGTCCAGA CCGGCAGCGG CCCGGTCAGC CGCACCTTCC ACGACACCCG 1140 CTACGGCCCG GTGGCCGTGG TGCCGGGCAC CTTCGACTGG ACGCCGGCCA CCGCGTACGC 1200 CATCACCGAC GTCAACGCGG GCAACAACCG CGCCTTCGAC GGGTGGCTGC GGATGGGCCA 1260 GGCCAAGGAC GTCCGGGCGC TCAAGGCGGT CCTCGACCGG CACCAGTTCC TGCCCTGGGT 1320 CAACGTGATC GCCGCCGACG CGCGGGGCGA GGCCCTCTAC GGCGATCATT CGGTCGTCCC 1380 CCGGGTGACC GGCGCGCTCG CTGCCGCCTG CATCCCGGCG CCGTTCCAGC CGCTCTACGC 1440 CTCCAGCGGC CAGGCGGTCC TGGACGGTTC CCGGTCGGAC TGCGCGCTCG GCGCCGACCC 1500 CGACGCCGCG GTCCCGGGCA TTCTCGGCCC GGCGAGCCTG CCGGTGCGGT TCCGCGACGA 1560 CTACGTCACC AACTCCAACG ACAGTCACTG GCTGGCCAGC CCGGCCGCCC CGCTGGAAGG 1620 CTTCCCGCGG ATCCTCGGCA ACGAACGCAC CCCGCGCAGC CTGCGCACCC GGCTCGGGCT 1680 GGACCAGATC CAGCAGCGCC TCGCCGGCAC GGACGGTCTG CCCGGCAAGG GCTTCACCAC 1740 CGCCCGGCTC TGGCAGGTCA TGTTCGGCAA CCGGATGCAC GGCGCCGAAC TCGTCCGCGA 1800 CGACCTGGTC GCGCTCTGCC GCCGCCAGCC GACCGCGACC GCCTCGAACG GCGCGATCGT 1860 CGACCTCACC GCGGCCTGCA CGGCGCTGTC CCGCTTCGAT GAGCGTGCCG ACCTGGACAG 1920 CCGGGGCGCG CACCTGTTCA CCGAGTTCGC CCTCGCGGGC GGAATCAGGT TCGCCGACAC 1980 CTTCGAGGTG ACCGATCCGG TACGCACCCC GCGCCGTCTG AACACCACGG ATCCGCGGGT 2040 ACGGACGGCG CTCGCCGACG CCGTGCAACG GCTCGCCGGC ATCCCCCTCG ACGCGAAGCT 2100 GGGAGACATC CACACCGACA GCCGCGGCGA ACGGCGCATC CCCATCCACG GTGGCCGCGG 2160 GGAAGCAGGC ACCTTCAACG TGATCACCAA CCCGCTCGTG CCGGGCGTGG GATACCCGCA 2220 GGTCGTCCAC GGAACATCGT TCGTGATGGC CGTCGAACTC GGCCCGCACG GCCCGTCGGG 2280 ACGGCAGATC CTCACCTATG CGCAGTCGAC GAACCCGAAC TCACCCTGGT ACGCCGACCA 2340 GACCGTGCTC TACTCGCGGA AGGGCTGGGA CACCATCAAG TACACCGAGG CGCAGATCGC 2400 GGCCGACCCG AACCTGCGCG TCTACCGGGT GGCACAGCGG GGACGCTGAC CCACGTCACG 2460 CCGGCTCGGC CCGTGCGGGG GCGCAGGGCG CCGATCGTCT CTGCATCGCC GGTCAGCCGG 2520 GGCCTGCGTC GACCGGCGGC GGCCGGTCGA CGCCCGCGTC CCGGCGCAGC GACTGGCTGA 2580 AGCGCCAGGC GTCGGCGGCC CGGGGCAGGT TGTTGAACAT CACGTACGCC GGGCCGCCGT 2640 CGAGGATGCC GGCGAGGTGT GCCAGCTCGG CATCCGTGTA CACATGCCGG GCGCCGGTGA 2700 TGCCGTGCAG CCGGTAATAG GCCATCGGCG TCAGACTGCG GCGCAGGAAC GGGTCGGCGG 2760 CGTGGGTCAG GTCCAGCTCC TGGCACAAGC CCTCGACCAC CTCGTCCGGC CACGGGCCGC 2820 GCGGCTCCCA CAACAGCCGG ACACCGGCCG GCCGGCGCGC TCGGGCGCAG AACTCACGCA 2880 GTCGCGCGAT GGCGGGTTCG GTCGGCCGGA AACTCGCCGG GCACTGCAG 2929 782 amino acids amino acid linear peptide 32 Met Arg Leu Lys Ala Ala Ala Ile Ala Phe Gly Val Ile Val Ala Thr 5 10 15 Ala Thr Val Pro Ser Pro Ala Ser Gly Arg Glu His Asp Gly Gly Tyr 20 25 30 Ala Ala Leu Ile Arg Arg Ala Ser Tyr Gly Val Pro His Ile Thr Ala 35 40 45 Asp Asp Phe Gly Ser Leu Gly Phe Gly Val Gly Tyr Val Gln Ala Glu 50 55 60 Asp Asn Ile Cys Val Ile Ala Glu Ser Val Val Thr Ala Asn Gly Glu 65 70 75 80 Arg Ser Arg Trp Phe Gly Ala Thr Gly Pro Asp Asp Ala Asp Val Arg 85 90 95 Ser Asp Leu Phe His Arg Lys Ala Ile Asp Asp Arg Val Ala Glu Arg 100 105 110 Leu Leu Glu Gly Pro Arg Asp Gly Val Arg Ala Pro Ser Asp Asp Val 115 120 125 Arg Asp Gln Met Arg Gly Phe Val Ala Gly Tyr Asn His Phe Leu Arg 130 135 140 Arg Thr Gly Val His Arg Leu Thr Asp Pro Ala Cys Arg Gly Lys Ala 145 150 155 160 Trp Val Arg Pro Leu Ser Glu Ile Asp Leu Trp Arg Thr Leu Trp Asp 165 170 175 Ser Met Val Arg Ala Gly Ser Gly Ala Leu Leu Asp Gly Ile Val Ala 180 185 190 Ala Thr Pro Pro Thr Ala Ala Gly Pro Ala Ser Ala Pro Glu Ala Pro 195 200 205 Asp Ala Ala Ala Ile Ala Ala Ala Leu Asp Gly Thr Ser Ala Gly Ile 210 215 220 Gly Ser Asn Ala Tyr Gly Leu Gly Ala Gln Ala Thr Val Asn Gly Ser 225 230 235 240 Gly Met Val Leu Ala Asn Pro His Phe Pro Trp Gln Gly Ala Ala Arg 245 250 255 Phe Tyr Arg Met His Leu Lys Val Pro Gly Arg Tyr Asp Val Glu Gly 260 265 270 Ala Ala Leu Val Gly Asp Pro Ile Ile Glu Ile Gly His Asn Arg Thr 275 280 285 Val Ala Trp Ser His Thr Val Ser Thr Ala Arg Arg Phe Val Trp His 290 295 300 Arg Leu Ser Leu Val Pro Gly Asp Pro Thr Ser Tyr Tyr Val Asp Gly 305 310 315 320 Arg Pro Glu Arg Met Arg Ala Arg Thr Val Thr Val Gln Thr Gly Ser 325 330 335 Gly Pro Val Ser Arg Thr Phe His Asp Thr Arg Tyr Gly Pro Val Ala 340 345 350 Val Met Pro Gly Thr Phe Asp Trp Thr Pro Ala Thr Ala Tyr Ala Ile 355 360 365 Thr Asp Val Asn Ala Gly Asn Asn Arg Ala Phe Asp Gly Trp Leu Arg 370 375 380 Met Gly Gln Ala Lys Asp Val Arg Ala Leu Lys Ala Val Leu Asp Arg 385 390 395 400 His Gln Phe Leu Pro Trp Val Asn Val Ile Ala Ala Asp Ala Arg Gly 405 410 415 Glu Ala Leu Tyr Gly Asp His Ser Val Val Pro Arg Val Thr Gly Ala 420 425 430 Leu Ala Ala Ala Cys Ile Pro Ala Pro Phe Gln Pro Leu Tyr Ala Ser 435 440 445 Ser Gly Gln Ala Val Leu Asp Gly Ser Arg Ser Asp Cys Ala Leu Gly 450 455 460 Ala Asp Pro Asp Ala Ala Val Pro Gly Ile Leu Gly Pro Ala Ser Leu 465 470 475 480 Pro Val Arg Phe Arg Asp Asp Tyr Val Thr Asn Ser Asn Asp Ser His 485 490 495 Trp Leu Ala Ser Pro Ala Ala Pro Leu Glu Gly Phe Pro Arg Ile Leu 500 505 510 Gly Asn Glu Arg Thr Pro Arg Ser Leu Arg Thr Arg Leu Gly Leu Asp 515 520 525 Gln Ile Gln Gln Arg Leu Ala Gly Thr Asp Gly Leu Pro Gly Lys Gly 530 535 540 Phe Thr Thr Ala Arg Leu Trp Gln Val Met Phe Gly Asn Arg Met His 545 550 555 560 Gly Ala Glu Leu Ala Arg Asp Asp Leu Val Ala Leu Cys Arg Arg Gln 565 570 575 Pro Thr Ala Thr Ala Ser Asn Gly Ala Ile Val Asp Leu Thr Ala Ala 580 585 590 Cys Thr Ala Leu Ser Arg Phe Asp Glu Arg Ala Asp Leu Asp Ser Arg 595 600 605 Gly Ala His Leu Phe Thr Glu Phe Ala Leu Ala Gly Gly Ile Arg Phe 610 615 620 Ala Asp Thr Phe Glu Val Thr Asp Pro Val Arg Thr Pro Arg Arg Leu 625 630 635 640 Asn Thr Thr Asp Pro Arg Val Arg Thr Ala Leu Ala Asp Ala Val Gln 645 650 655 Arg Leu Ala Gly Ile Pro Leu Asp Ala Lys Leu Gly Asp Ile His Thr 660 665 670 Asp Ser Arg Gly Glu Arg Arg Ile Pro Ile His Gly Gly Arg Gly Glu 675 680 685 Ala Gly Thr Phe Asn Val Ile Thr Asn Pro Leu Val Pro Gly Val Gly 690 695 700 Tyr Pro Gln Val Val His Gly Thr Ser Phe Val Met Ala Val Glu Leu 705 715 715 720 Gly Pro His Gly Pro Ser Gly Arg Gln Ile Leu Thr Tyr Ala Gln Ser 725 730 735 Thr Asn Pro Asn Ser Pro Trp Tyr Ala Asp Gln Thr Val Leu Tyr Ser 740 745 750 Arg Lys Gly Trp Asp Thr Ile Lys Tyr Thr Glu Ala Gln Ile Ala Ala 755 760 765 Asp Pro Asn Leu Arg Val Tyr Arg Val Ala Gln Arg Gly Arg 770 775 780 782 782 amino acids amino acid linear peptide 33 Met Arg Leu Lys Ala Ala Ala Ile Ala Phe Gly Val Ile Val Ala Thr 5 10 15 Ala Ala Val Pro Ser Pro Ala Ser Gly Arg Glu His Asp Gly Gly Tyr 20 25 30 Ala Ala Leu Ile Arg Arg Ala Ser Tyr Gly Val Pro His Ile Thr Ala 35 40 45 Asp Asp Phe Gly Ser Leu Gly Phe Gly Val Gly Tyr Val Gln Ala Glu 50 55 60 Asp Asn Ile Cys Val Ile Ala Glu Ser Val Val Thr Ala Asn Gly Glu 65 70 75 80 Arg Ser Arg Trp Phe Gly Ala Thr Gly Pro Asp Asp Ala Asp Val Arg 85 90 95 Ser Asp Leu Phe His Arg Lys Ala Ile Asp Asp Arg Val Ala Glu Arg 100 105 110 Leu Leu Glu Gly Pro Arg Asp Gly Val Arg Ala Pro Ser Asp Asp Val 115 120 125 Arg Asp Gln Met Arg Gly Phe Val Ala Gly Tyr Asn His Phe Leu Arg 130 135 140 Arg Thr Gly Val His Arg Leu Thr Asp Pro Ala Cys Arg Gly Lys Ala 145 150 155 160 Trp Val Arg Pro Leu Ser Glu Ile Asp Leu Trp Arg Thr Ser Trp Asp 165 170 175 Ser Met Val Arg Ala Gly Ser Gly Ala Leu Leu Asp Gly Ile Val Ala 180 185 190 Ala Thr Pro Pro Thr Ala Ala Gly Pro Ala Ser Ala Pro Glu Ala Pro 195 200 205 Asp Ala Ala Ala Ile Ala Ala Ala Leu Asp Gly Thr Ser Ala Gly Ile 210 215 220 Gly Ser Asn Ala Tyr Gly Leu Gly Ala Gln Ala Thr Val Asn Gly Ser 225 230 235 240 Gly Met Val Leu Ala Asn Pro His Phe Pro Trp Gln Gly Ala Glu Arg 245 250 255 Phe Tyr Arg Met His Leu Lys Val Pro Gly Arg Tyr Asp Val Glu Gly 260 265 270 Ala Ala Leu Ile Gly Asp Pro Ile Ile Gly Ile Gly His Asn Arg Thr 275 280 285 Val Ala Trp Ser His Thr Val Ser Thr Ala Arg Arg Phe Val Trp His 290 295 300 Arg Leu Ser Leu Val Pro Gly Asp Pro Thr Ser Tyr Tyr Val Asp Gly 305 310 315 320 Arg Pro Glu Arg Met Arg Ala Arg Thr Val Thr Val Gln Thr Gly Ser 325 330 335 Gly Pro Val Ser Arg Thr Phe His Asp Thr Arg Tyr Gly Pro Val Ala 340 345 350 Val Met Pro Gly Thr Phe Asp Trp Thr Pro Ala Thr Ala Tyr Ala Ile 355 360 365 Thr Asp Val Asn Ala Gly Asn Asn Arg Ala Phe Asp Gly Trp Leu Arg 370 375 380 Met Gly Gln Ala Lys Asp Val Arg Ala Leu Lys Ala Val Leu Asp Arg 385 390 395 400 His Gln Phe Leu Pro Trp Val Asn Val Ile Ala Ala Asp Ala Arg Gly 405 410 415 Glu Ala Leu Tyr Gly Asp His Ser Val Val Pro Arg Val Thr Gly Ala 420 425 430 Leu Ala Ala Ala Cys Ile Pro Ala Pro Phe Gln Pro Leu Tyr Ala Ser 435 440 445 Ser Gly Gln Ala Val Leu Asp Gly Ser Arg Ser Asp Cys Ala Leu Gly 450 455 460 Ala Asp Pro Asp Ala Ala Val Pro Gly Ile Leu Gly Pro Ala Ser Leu 465 470 475 480 Pro Val Arg Phe Arg Asp Asp Tyr Val Thr Asn Ser Asn Asp Ser His 485 490 495 Trp Leu Ala Ser Pro Ala Ala Pro Leu Glu Gly Phe Pro Arg Ile Leu 500 505 510 Gly Asn Glu Arg Thr Pro Arg Ser Leu Arg Thr Arg Leu Gly Leu Asp 515 520 525 Gln Ile Gln Gln Arg Leu Ala Gly Thr Asp Gly Leu Pro Gly Lys Gly 530 535 540 Phe Thr Thr Ala Arg Leu Trp Gln Val Met Phe Gly Asn Arg Met His 545 550 555 560 Gly Ala Glu Leu Ala Arg Asp Asp Leu Val Ala Leu Cys Arg Arg Gln 565 570 575 Pro Thr Ala Thr Ala Ser Asn Gly Ala Ile Val Asp Leu Thr Ala Ala 580 585 590 Cys Thr Ala Leu Ser Arg Phe Asp Glu Arg Ala Asp Leu Asp Ser Arg 595 600 605 Gly Ala His Leu Phe Thr Glu Phe Ala Leu Ala Gly Gly Ile Arg Phe 610 615 620 Ala Asp Thr Phe Glu Val Thr Asp Pro Val Arg Thr Pro Arg Arg Leu 625 630 635 640 Asn Thr Thr Asp Pro Arg Val Arg Thr Ala Leu Ala Asp Ala Val Gln 645 650 655 Arg Leu Ala Gly Ile Pro Leu Asp Ala Lys Leu Gly Asp Ile His Thr 660 665 670 Asp Ser Arg Gly Glu Arg Arg Ile Pro Ile His Gly Gly Arg Gly Glu 675 680 685 Ala Gly Thr Phe Asn Val Ile Thr Asn Pro Leu Val Pro Gly Val Gly 690 695 700 Tyr Pro Gln Val Val His Gly Thr Ser Phe Val Met Ala Val Glu Leu 705 715 715 720 Gly Pro His Gly Pro Ser Gly Arg Gln Ile Leu Thr Tyr Ala Gln Ser 725 730 735 Thr Asn Pro Asn Ser Pro Trp Tyr Ala Asp Gln Thr Val Leu Tyr Ser 740 745 750 Arg Lys Gly Trp Asp Thr Ile Lys Tyr Thr Glu Ala Gln Ile Ala Ala 755 760 765 Asp Pro Asn Leu Arg Val Tyr Arg Val Ala Gln Arg Gly Arg 770 775 780 782 782 amino acids amino acid linear peptide 34 Met Arg Leu Lys Ala Ala Ala Ile Ala Phe Gly Val Ile Val Ala Thr 5 10 15 Ala Thr Val Pro Ser Pro Ala Ser Gly Arg Glu His Asp Gly Gly Tyr 20 25 30 Ala Ala Leu Ile Arg Arg Ala Ser Tyr Gly Val Pro His Ile Thr Ala 35 40 45 Asp Asp Phe Gly Ser Leu Gly Phe Gly Val Gly Tyr Val Gln Ala Glu 50 55 60 Asp Asn Ile Cys Val Ile Ala Glu Ser Val Val Thr Ala Asn Gly Glu 65 70 75 80 Arg Ser Arg Trp Phe Gly Ala Thr Gly Pro Asp Asp Ala Asp Val Arg 85 90 95 Ser Asp Leu Phe His Arg Lys Ala Ile Asp Asp Arg Val Ala Glu Arg 100 105 110 Leu Leu Glu Gly Pro Arg Asp Gly Val Arg Ala Pro Ser Asp Asp Val 115 120 125 Arg Asp Gln Met Arg Gly Phe Val Ala Gly Tyr Asn His Phe Leu Arg 130 135 140 Arg Thr Gly Val His Arg Leu Thr Asp Pro Ala Cys Arg Gly Lys Ala 145 150 155 160 Trp Val Arg Pro Leu Ser Glu Ile Asp Leu Trp Arg Thr Leu Trp Asp 165 170 175 Ser Met Val Arg Ala Gly Ser Gly Ala Leu Leu Asp Gly Ile Val Ala 180 185 190 Ala Thr Pro Pro Thr Ala Ala Gly Pro Ala Ser Ala Pro Glu Ala Pro 195 200 205 Asp Ala Ala Ala Ile Ala Ala Ala Leu Asp Gly Thr Ser Ala Gly Ile 210 215 220 Gly Ser Asn Ala Tyr Gly Leu Gly Ala Gln Ala Thr Val Asn Gly Ser 225 230 235 240 Gly Met Val Leu Ala Asn Pro His Phe Pro Trp Gln Gly Ala Ala Arg 245 250 255 Phe Tyr Arg Met His Leu Lys Val Pro Gly Arg Tyr Asp Val Glu Gly 260 265 270 Ala Ala Leu Val Gly Asp Pro Ile Ile Glu Ile Gly His Asn Arg Thr 275 280 285 Val Ala Trp Ser His Thr Val Ser Thr Ala Arg Arg Phe Val Trp His 290 295 300 Arg Leu Ser Leu Val Pro Gly Asp Pro Thr Ser Tyr Tyr Val Asp Gly 305 310 315 320 Arg Pro Glu Arg Met Arg Ala Arg Thr Val Thr Val Gln Thr Gly Ser 325 330 335 Gly Pro Val Ser Arg Thr Phe His Asp Thr Arg Tyr Gly Pro Val Ala 340 345 350 Val Val Pro Gly Thr Phe Asp Trp Thr Pro Ala Thr Ala Tyr Ala Ile 355 360 365 Thr Asp Val Asn Ala Gly Asn Asn Arg Ala Phe Asp Gly Trp Leu Arg 370 375 380 Met Gly Gln Ala Lys Asp Val Arg Ala Leu Lys Ala Val Leu Asp Arg 385 390 395 400 His Gln Phe Leu Pro Trp Val Asn Val Ile Ala Ala Asp Ala Arg Gly 405 410 415 Glu Ala Leu Tyr Gly Asp His Ser Val Val Pro Arg Val Thr Gly Ala 420 425 430 Leu Ala Ala Ala Cys Ile Pro Ala Pro Phe Gln Pro Leu Tyr Ala Ser 435 440 445 Ser Gly Gln Ala Val Leu Asp Gly Ser Arg Ser Asp Cys Ala Leu Gly 450 455 460 Ala Asp Pro Asp Ala Ala Val Pro Gly Ile Leu Gly Pro Ala Ser Leu 465 470 475 480 Pro Val Arg Phe Arg Asp Asp Tyr Val Thr Asn Ser Asn Asp Ser His 485 490 495 Trp Leu Ala Ser Pro Ala Ala Pro Leu Glu Gly Phe Pro Arg Ile Leu 500 505 510 Gly Asn Glu Arg Thr Pro Arg Ser Leu Arg Thr Arg Leu Gly Leu Asp 515 520 525 Gln Ile Gln Gln Arg Leu Ala Gly Thr Asp Gly Leu Pro Gly Lys Gly 530 535 540 Phe Thr Thr Ala Arg Leu Trp Gln Val Met Phe Gly Asn Arg Met His 545 550 555 560 Gly Ala Glu Leu Val Arg Asp Asp Leu Val Ala Leu Cys Arg Arg Gln 565 570 575 Pro Thr Ala Thr Ala Ser Asn Gly Ala Ile Val Asp Leu Thr Ala Ala 580 585 590 Cys Thr Ala Leu Ser Arg Phe Asp Glu Arg Ala Asp Leu Asp Ser Arg 595 600 605 Gly Ala His Leu Phe Thr Glu Phe Ala Leu Ala Gly Gly Ile Arg Phe 610 615 620 Ala Asp Thr Phe Glu Val Thr Asp Pro Val Arg Thr Pro Arg Arg Leu 625 630 635 640 Asn Thr Thr Asp Pro Arg Val Arg Thr Ala Leu Ala Asp Ala Val Gln 645 650 655 Arg Leu Ala Gly Ile Pro Leu Asp Ala Lys Leu Gly Asp Ile His Thr 660 665 670 Asp Ser Arg Gly Glu Arg Arg Ile Pro Ile His Gly Gly Arg Gly Glu 675 680 685 Ala Gly Thr Phe Asn Val Ile Thr Asn Pro Leu Val Pro Gly Val Gly 690 695 700 Tyr Pro Gln Val Val His Gly Thr Ser Phe Val Met Ala Val Glu Leu 705 715 715 720 Gly Pro His Gly Pro Ser Gly Arg Gln Ile Leu Thr Tyr Ala Gln Ser 725 730 735 Thr Asn Pro Asn Ser Pro Trp Tyr Ala Asp Gln Thr Val Leu Tyr Ser 740 745 750 Arg Lys Gly Trp Asp Thr Ile Lys Tyr Thr Glu Ala Gln Ile Ala Ala 755 760 765 Asp Pro Asn Leu Arg Val Tyr Arg Val Ala Gln Arg Gly Arg 770 775 780 782 782 amino acids amino acid linear peptide 35 Met Arg Leu Lys Ala Ala Ala Ile Ala Phe Gly Val Ile Val Ala Thr 5 10 15 Ala Thr Val Pro Ser Pro Ala Ser Gly Arg Glu His Asp Gly Gly Tyr 20 25 30 Ala Ala Leu Ile Arg Arg Ala Ser Tyr Gly Val Pro His Ile Thr Ala 35 40 45 Asp Asp Phe Gly Ser Leu Gly Phe Gly Val Gly Tyr Val Gln Ala Glu 50 55 60 Asp Asn Ile Cys Val Ile Ala Glu Ser Val Val Thr Ala Asn Gly Glu 65 70 75 80 Arg Ser Arg Trp Phe Gly Ala Thr Gly Pro Asp Asp Ala Asp Val Arg 85 90 95 Ser Asp Leu Phe His Arg Lys Ala Ile Asp Asp Arg Val Ala Glu Arg 100 105 110 Leu Leu Glu Gly Pro Arg Asp Gly Val Arg Ala Pro Ser Asp Asp Val 115 120 125 Arg Asp Gln Met Arg Gly Phe Val Ala Gly Tyr Asn His Phe Leu Arg 130 135 140 Arg Thr Gly Val His Arg Leu Thr Asp Pro Ala Cys Arg Gly Lys Ala 145 150 155 160 Trp Val Arg Pro Leu Ser Glu Ile Asp Leu Trp Arg Thr Leu Trp Asp 165 170 175 Ser Met Val Arg Ala Gly Ser Gly Ala Leu Leu Asp Gly Ile Val Ala 180 185 190 Ala Thr Pro Pro Thr Ala Ala Gly Pro Ala Ser Ala Pro Glu Ala Pro 195 200 205 Asp Ala Ala Ala Ile Ala Ala Ala Leu Asp Gly Thr Ser Ala Gly Ile 210 215 220 Gly Ser Asn Ala Tyr Gly Leu Gly Ala Gln Ala Thr Val Asn Gly Ser 225 230 235 240 Gly Met Val Leu Ala Asn Pro His Phe Pro Trp Gln Gly Ala Ala Arg 245 250 255 Phe Tyr Arg Met His Leu Lys Val Pro Gly Arg Tyr Asp Val Glu Gly 260 265 270 Ala Ala Leu Val Gly Asp Pro Ile Ile Glu Ile Gly His Asn Arg Thr 275 280 285 Val Ala Trp Ser His Thr Val Ser Thr Ala Arg Arg Phe Val Trp His 290 295 300 Arg Leu Ser Leu Val Pro Gly Asp Pro Thr Ser Tyr Tyr Val Asp Gly 305 310 315 320 Arg Pro Glu Arg Met Arg Ala Arg Thr Val Thr Val Gln Thr Gly Ser 325 330 335 Gly Pro Val Ser Arg Thr Phe His Asp Thr Arg Tyr Gly Pro Val Ala 340 345 350 Val Val Pro Gly Thr Phe Asp Trp Thr Pro Ala Thr Ala Tyr Ala Ile 355 360 365 Thr Asp Val Asn Ala Gly Asn Asn Arg Ala Phe Asp Gly Trp Leu Arg 370 375 380 Met Gly Gln Ala Lys Asp Val Arg Ala Leu Lys Ala Val Leu Asp Arg 385 390 395 400 His Gln Phe Leu Pro Trp Val Asn Val Ile Ala Ala Asp Ala Arg Gly 405 410 415 Glu Ala Leu Tyr Gly Asp His Ser Val Val Pro Arg Val Thr Gly Ala 420 425 430 Leu Ala Ala Ala Cys Ile Pro Ala Pro Phe Gln Pro Leu Tyr Ala Ser 435 440 445 Ser Gly Gln Ala Val Leu Asp Gly Ser Arg Ser Asp Cys Ala Leu Gly 450 455 460 Ala Asp Pro Asp Ala Ala Val Pro Gly Ile Leu Gly Pro Ala Ser Leu 465 470 475 480 Pro Val Arg Phe Arg Asp Asp Tyr Val Thr Asn Ser Asn Asp Ser His 485 490 495 Trp Leu Ala Ser Pro Ala Ala Pro Leu Glu Gly Phe Pro Arg Ile Leu 500 505 510 Gly Asn Glu Arg Thr Pro Arg Ser Leu Arg Thr Arg Leu Gly Leu Asp 515 520 525 Gln Ile Gln Gln Arg Leu Ala Gly Thr Asp Gly Leu Pro Gly Lys Gly 530 535 540 Phe Thr Thr Ala Arg Leu Trp Gln Val Met Phe Gly Asn Arg Met His 545 550 555 560 Gly Ala Glu Leu Val Arg Asp Asp Leu Val Ala Leu Cys Arg Arg Gln 565 570 575 Pro Thr Ala Thr Ala Ser Asn Gly Ala Ile Val Asp Leu Thr Ala Ala 580 585 590 Cys Thr Ala Leu Ser Arg Phe Asp Glu Arg Ala Asp Leu Asp Ser Arg 595 600 605 Gly Ala His Leu Phe Thr Glu Phe Ala Leu Ala Gly Gly Ile Arg Phe 610 615 620 Ala Asp Thr Phe Glu Val Thr Asp Pro Val Arg Thr Pro Arg Arg Leu 625 630 635 640 Asn Thr Thr Asp Pro Arg Val Arg Thr Ala Leu Ala Asp Ala Val Gln 645 650 655 Arg Leu Ala Gly Ile Pro Leu Asp Ala Lys Leu Gly Asp Ile His Thr 660 665 670 Asp Ser Arg Gly Glu Arg Arg Ile Pro Ile His Gly Gly Arg Gly Glu 675 680 685 Ala Gly Thr Phe Asn Val Ile Thr Asn Pro Leu Val Pro Gly Val Gly 690 695 700 Tyr Pro Gln Val Val His Gly Thr Ser Phe Val Met Ala Val Glu Leu 705 715 715 720 Gly Pro His Gly Pro Ser Gly Arg Gln Ile Leu Thr Tyr Ala Gln Ser 725 730 735 Thr Asn Pro Asn Ser Pro Trp Tyr Ala Asp Gln Thr Val Leu Tyr Ser 740 745 750 Arg Lys Gly Trp Asp Thr Ile Lys Tyr Thr Glu Ala Gln Ile Ala Ala 755 760 765 Asp Pro Asn Leu Arg Val Tyr Arg Val Ala Gln Arg Gly Arg 770 775 780 782 782 amino acids amino acid linear peptide 36 Met Arg Leu Lys Ala Ala Ala Ile Ala Phe Gly Val Ile Val Ala Thr 5 10 15 Ala Ala Val Pro Ser Pro Ala Ser Gly Arg Glu His Asp Gly Gly Tyr 20 25 30 Ala Ala Leu Ile Arg Arg Ala Ser Tyr Gly Val Pro His Ile Thr Ala 35 40 45 Asp Asp Phe Gly Ser Leu Gly Phe Gly Val Gly Tyr Val Gln Ala Glu 50 55 60 Asp Asn Ile Cys Val Ile Ala Glu Ser Val Val Thr Ala Asn Gly Glu 65 70 75 80 Arg Ser Arg Trp Phe Gly Ala Thr Gly Pro Asp Asp Ala Asp Val Arg 85 90 95 Ser Asp Leu Phe His Arg Lys Ala Ile Asp Asp Arg Val Ala Glu Arg 100 105 110 Leu Leu Glu Gly Pro Arg Asp Gly Val Arg Ala Pro Ser Asp Asp Val 115 120 125 Arg Asp Gln Met Arg Gly Phe Val Ala Gly Tyr Asn His Phe Leu Arg 130 135 140 Arg Thr Gly Val His Arg Leu Thr Asp Pro Ala Cys Arg Gly Lys Ala 145 150 155 160 Trp Val Arg Pro Leu Ser Glu Ile Asp Leu Trp Arg Thr Ser Trp Asp 165 170 175 Ser Met Val Arg Ala Gly Ser Gly Ala Leu Leu Asp Gly Ile Val Ala 180 185 190 Ala Thr Pro Pro Thr Ala Ala Gly Pro Ala Ser Ala Pro Glu Ala Pro 195 200 205 Asp Ala Ala Ala Ile Ala Ala Ala Leu Asp Gly Thr Ser Ala Gly Ile 210 215 220 Gly Ser Asn Ala Tyr Gly Leu Gly Ala Gln Ala Thr Val Asn Gly Ser 225 230 235 240 Gly Met Val Leu Ala Asn Pro His Phe Pro Trp Gln Gly Ala Glu Arg 245 250 255 Phe Tyr Arg Met His Leu Lys Val Pro Gly Arg Tyr Asp Val Glu Gly 260 265 270 Ala Ala Leu Ile Gly Asp Pro Ile Ile Gly Ile Gly His Asn Arg Thr 275 280 285 Val Ala Trp Ser His Thr Val Ser Thr Ala Arg Arg Phe Val Trp His 290 295 300 Arg Leu Ser Leu Val Pro Gly Asp Pro Thr Ser Tyr Tyr Val Asp Gly 305 310 315 320 Arg Pro Glu Arg Met Arg Ala Arg Thr Val Thr Val Gln Thr Gly Ser 325 330 335 Gly Pro Val Ser Arg Thr Phe His Asp Thr Arg Tyr Gly Pro Val Ala 340 345 350 Val Met Pro Gly Thr Phe Asp Trp Thr Pro Ala Thr Ala Tyr Ala Ile 355 360 365 Thr Asp Val Asn Ala Gly Asn Asn Arg Ala Phe Asp Gly Trp Leu Arg 370 375 380 Met Gly Gln Ala Lys Asp Val Arg Ala Leu Lys Ala Val Leu Asp Arg 385 390 395 400 His Gln Phe Leu Pro Trp Val Asn Val Ile Ala Ala Asp Ala Arg Gly 405 410 415 Glu Ala Leu Tyr Gly Asp His Ser Val Val Pro Arg Val Thr Gly Ala 420 425 430 Leu Ala Ala Ala Cys Ile Pro Ala Pro Phe Gln Pro Leu Tyr Ala Ser 435 440 445 Ser Gly Gln Ala Val Leu Asp Gly Ser Arg Ser Asp Cys Ala Leu Gly 450 455 460 Ala Asp Pro Asp Ala Ala Val Pro Gly Ile Leu Gly Pro Ala Ser Leu 465 470 475 480 Pro Val Arg Phe Arg Asp Asp Tyr Val Thr Asn Ser Asn Asp Ser His 485 490 495 Trp Leu Ala Ser Pro Ala Ala Pro Leu Glu Gly Phe Pro Arg Ile Leu 500 505 510 Gly Asn Glu Arg Thr Pro Arg Ser Leu Arg Thr Arg Leu Gly Leu Asp 515 520 525 Gln Ile Gln Gln Arg Leu Ala Gly Thr Asp Gly Leu Pro Gly Lys Gly 530 535 540 Phe Thr Thr Ala Arg Leu Trp Gln Val Met Phe Gly Asn Arg Met His 545 550 555 560 Gly Ala Glu Leu Ala Arg Asp Asp Leu Val Ala Leu Cys Arg Arg Gln 565 570 575 Pro Thr Ala Thr Ala Ser Asn Gly Ala Ile Val Asp Leu Thr Ala Ala 580 585 590 Cys Thr Ala Leu Ser Arg Phe Asp Glu Arg Ala Asp Leu Asp Ser Arg 595 600 605 Gly Ala His Leu Phe Thr Glu Phe Ala Leu Ala Gly Gly Ile Arg Phe 610 615 620 Ala Asp Thr Phe Glu Val Thr Asp Pro Val Arg Thr Pro Arg Arg Leu 625 630 635 640 Asn Thr Thr Asp Pro Arg Val Arg Thr Ala Leu Ala Asp Ala Val Gln 645 650 655 Arg Leu Ala Gly Ile Pro Leu Asp Ala Lys Leu Gly Asp Ile His Thr 660 665 670 Asp Ser Arg Gly Glu Arg Arg Ile Pro Ile His Gly Gly Arg Gly Glu 675 680 685 Ala Gly Thr Phe Asn Val Ile Thr Asn Pro Leu Val Pro Gly Val Gly 690 695 700 Tyr Pro Gln Val Val His Gly Thr Ser Phe Val Met Ala Val Glu Leu 705 715 715 720 Gly Pro His Gly Pro Ser Gly Arg Gln Ile Leu Thr Tyr Ala Gln Ser 725 730 735 Thr Asn Pro Asn Ser Pro Trp Tyr Ala Asp Gln Thr Val Leu Tyr Ser 740 745 750 Arg Lys Gly Trp Asp Thr Ile Lys Tyr Thr Glu Ala Gln Ile Ala Ala 755 760 765 Asp Pro Asn Leu Arg Val Tyr Arg Val Ala Gln Arg Gly Arg 770 775 780 782 

What is claimed is:
 1. An isolated enzyme which exhibits echinocandin B (ECB) deacylase activity, said enzyme having an amino acid sequence which is selected from the group consisting of SEQ ID NOS: 32, 33, 34, 35 and
 36. 2. An isolated enzyme which exhibits ECB activity, said enzyme being made by a method comprising the steps of: a) inserting into a vector a double-stranded mutagenized polynucleotide having the sequence of SEQ ID NO: 26, 27, 28, 29 or 30 to form an expression vector, wherein said mutagenized polynucleotide encodes ECB deacylase; b) transforinng a host cell with said vector of step a); c) culturing the transformed host cell of step b) expressing the ECB deacylase encoded by said mutagenized polynucleotide; and d) recovering the ECB deacylase so produced from the culture. 